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Structural basis for sulfatide recognition by Disabled-2Song, Wei 12 January 2021 (has links)
Disabled-2 (Dab2) is an adaptor protein that plays critical roles in various biological processes, including protein endocytosis, platelet activation and aggregation, tumor growth, and development. In platelets, Dab2 associates with membrane sulfatide at the platelet surface, modulating platelet inside-out and outside-in signaling pathways. A Dab2-derived peptide, named the sulfatide-binding peptide (SBP), is the minimal unit of Dab2 to exert its function as a negative regulator of platelet activation and aggregation. The work of this thesis refines the model of Dab2 SBP binding to sulfatide and provides structural and functional insights into the mechanism by which Dab2 SBP modulates platelet activation.
Using molecular docking, lipid-protein overlay assay, nuclear magnetic resonance, and surface plasma resonance tools, this work identifies the critical residues within two major regions responsible for sulfatide interaction. First, docking a sulfatide to Dab2 SBP, a hydrophilic region, primarily mediated by Arg42, is thought to be responsible for the association with the sulfatide headgroup. We observed that Arg 42 could directly interact with sulfatide by forming hydrogen bonds with the OS atoms in the sulfatide head group. Further lipid-protein overlay assay and surface plasma resonance experiments confirmed that both the positive charge and stereochemistry of the side chain of Dab2 SBP Arg42 are required for the sulfatide binding. Moreover, Arg42 is found to be critical in the inhibition of P-selectin expression on activated platelets. The residues nearby Arg42 (i.e., Glu33, Ty38, and Lys 44) also contribute to sulfatide interaction. Second, the second polybasic motif located at the C-terminal -helix 2 is considered to interact with the acyl chain through hydrophobic interactions rather than direct binding to the charged sulfatide head group. Lysine residues in this region are suggested to exert a dual role in sulfatide association, that is, by favoring electrostatic interactions with the negatively-charged sulfatide and/or by employing their flexible hydrocarbon spacers for hydrophobic interactions with membrane lipids. Consistent with this suggestion, we found a hydrophobic patch in the wild type Dab2 SBP structure surrounded by Lys49, Lys51, and Lys53. Furthermore, the role of the second sulfatide binding motif in sulfatide binding is confirmed by mutagenesis analysis and lipid-protein overlay assays, highlighting the ability of molecular docking to accurately predict critical residues responsible for sulfatide binding.
In summary, this work provides a detailed structural basis for Dab2 recognition by sulfatide through multiple biophysical methods. The corresponding biological implications in the inhibition of platelet activation are also evaluated by flow cytometry. By elucidating the underlying mechanisms of Dab2 mediating platelet activation through sulfatide binding, we provided structural and functional insights for designing a Dab2-derived peptide with altered sulfatide recognition features in platelets, which can be further employed in antiplatelet therapy. / Doctor of Philosophy / Platelets are blood cells that are fundamentally intended to help form clots to stop bleeding. They do so by being activated after getting signals from damaged blood vessels and reaching the injury site. Consequently, they form aggregates by attracting more platelets to clump on the clot. However, platelet activation induced by a tumor cell can, in turn, protect the tumor cell from immune system elimination and facilitates their growth and spread. This platelet-tumor complex formation suggests platelets as a therapeutic target for reducing tumor migration out of the bloodstream. Our study investigates the mechanism of a Disabled-2-derived peptide, named Dab2 SBP, which upon binding to a sulfatide lipid, can reduce the platelet activation extent, using molecular and cellular approaches. The results of this study may be instrumental in the generation of Dab2 SBP-derived peptides with altered sulfatide binding ability and selectivity, which may lead to a design of an antiplatelet drug that can limit the ability of tumor cells to invade other tissues.
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NMR Investigations of Peptide-Membrane Interactions, Modulation of Peptide-Lipid Interaction as a Switch in Signaling across the Lipid BilayerUnnerståle, Sofia January 2010 (has links)
The complexity of multi cellular organisms demands systems that facilitate communicationbetween cells. The neurons in our brains for instance are specialized in this cell-cellcommunication. The flow of ions, through their different ion channels, across the membrane, isresponsible for almost all of the communication between neurons in the brain by changing theneurons membrane potentials. Voltage-gated ion channels open when a certain thresholdpotential is reached. This change in membrane potential is detected by voltage-sensors in the ionchannels. In this licentiate thesis the Homo sapiens voltage- and calcium-gated BK potassiumchannel (HsapBK) has been studied. The NMR solution structure of the voltage-sensor ofHsapBK was solved to shed light upon the voltage-gating in these channels. Structures of othervoltage-gated potassium channels (Kv) have been determined by other groups, enablingcomparison among different types of Kv channels. Interestingly, the peptide-lipid interactions ofthe voltage-sensor in HsapBK are crucial for its mechanism of action.Uni cellular organisms need to sense their environment too, to be able to move towardsmore favorable areas and from less favorable ones, and to adapt their gene profiles to currentcircumstances. This is accomplished by the two-component system, comprising a sensor proteinand a response regulator. The sensor protein transfers signals across the membrane to thecytoplasm. Many sensor proteins contain a HAMP domain close to the membrane that isinvolved in transmitting the signal. The mechanism of this transfer is not yet revealed. Ourstudies show that HAMP domains can be divided into two groups based on the membraneinteraction of their AS1 segments. Further, these two groups are suggested to work by differentmechanisms; one membrane-dependent and one membrane-independent mechanism.Both the voltage-gating mechanism and the signal transduction carried out by HAMPdomains in the membrane-dependent group, demand peptide-lipid interactions that can be readilymodulated. This modulation enables movement of peptides within membranes or within thelipid-water interface. These conditions make these peptides especially suitable for NMR studies.
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Membrane mediated aggregation of amyloid-β protein : a potential key event in Alzheimer's diseaseBokvist, Marcus January 2007 (has links)
The pathogenesis of Alzheimer’s disease (AD), the most common senile dementia, is a complex process. A crucial event in AD is the aggregation of amyloid-β protein (Aβ), a cleavage product from the Amyloid Precursor Protein (APP). Aβ40, a common component in amyloid plaques found in patients, aggregates in vitro at concentrations, much higher than the one found in vivo. But in the presence of charged lipid membranes, aggregations occurs at much lower concentration in vitro compared to the membrane-free case. This can be understood due to the ability of Aβ to get electrostatically attracted to target membranes with a pronounced surface potential. This electrostatically driven process accumulates peptide at the membrane surface at concentrations high enough for aggregation while the bulk concentration still remains below threshold. Here, we elucidated the molecular nature of this Aβ-membrane process and its consequences for Aβ misfolding by Circular Dichroism Spectroscopy, Differential Scanning Calorimetry and Nuclear Magnetic Resonance Spectroscopy. First, we revealed by NMR that Aβ40 peptide does indeed interact electrostatically with membranes of negative and positive surface potential. Surprisingly, it even binds to nominal neutral membranes if these contain lipids of opposite charge. Combined NMR and CD studies also revealed that the peptide might be shielded from aggregation when incorporated into the membrane. Moreover, CD studies of Aβ40 added to charged membranes showed that both positively and negatively membranes induce aggregation albeit at different kinetics and finally that macromolecular crowding can both speed up and slow down aggregation of Aβ.
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Plantaricina 149 e análogos: atividade antimicrobiana, estudos estruturais e mecanismos de ação / Plantaricin 149 and analogs: antimicrobial activity, structural studies and mechanisms of action.Lopes, José Luiz de Souza 19 March 2010 (has links)
Peptídeos antimicrobianos são vistos como alternativas promissoras a serem empregadas pela iindústria farmacêutica no controle de infecções causadas por microrganismos, como também na indústria alimentícia, onde podem desempenhar papéis como conservantes naturais de alimentos. Plantaricina149 é um membro deste grupo, sendo composto por 22 resíduos de aminoácidos, com natureza catiônica e atividade inibitória sobre algumas bactérias patogênicas. Neste trabalho, foram sintetizados diferentes peptídeos análogos à Plantaricina149 para investigar suas ações sobre microrganismos (bactérias e fungos), a fim de correlacionar estes estudos com a ação lítica do peptídeo em modelos de membrana diversos (monocamadas e vesículas fosfolipídicas). A interação de Plantaricina149 com estes sistemas foi monitorada pelas espectroscopias de dicroísmo circular e fluorescência, ensaios de tensão superficial, calorimetria e ressonância plasmônica de superfície, e mostrou ser altamente específica para superfícies fosfolipídicas que apresentam densidade de cargas negativas, tais como a membrana celular de bactérias. A interação eletrostática inicial que se estabelece entre o peptídeo e os fosfolipídios é de extrema importância, sendo capaz de induzir uma estruturação helicoidal na região C-terminal do peptídeo, enquanto a região Nterminal contribui com as interações hidrofóbicas necessárias para a penetração do peptídeo nas camadas fosfolipídicas levando a ruptura das mesmas. De forma semelhante, a atividade antimicrobiana de Plantaricina149a (e alguns de seus análogos) também mostrou ser resultado das interações das duas regiões da molécula, e foi afetada com a retirada ou modificação da região N-terminal do peptídeo. Com a deleção desta região, o peptídeo passou a ter somente ação bacteriostática sobre Staphylococcus aureus e Pseudomonas aeruginosa, perdendo a capacidade bactericida. / Antimicrobial peptides are seen as promising alternatives to be employed in pharmaceutical industry for controlling infections caused by microorganisms, and also in food industry, where they can play roles as natural food preservatives. Plantaricina149 is a member of this group, constituted of 22 amino acid residues, cationic in nature and presenting inhibitory activity against some pathogenic bacteria. In this work, different Plantaricina149 analog peptides were synthesized to investigate their action against microorganisms (bacteria and fungi), with the aim of correlating these studies with the lytic action of the peptide on several membrane models (phospholipid monolayers and vesicles). The Plantaricina149 interaction with these systems was monitored by circular dichroism and fluorescence spectroscopies, surface tension assays, calorimetry and surface plasmon resonance, and showed to be highly specific to phospholipid surfaces that present negative charge density, such as the bacteria cell membrane. The initial peptide-phospholipids electrostatic interaction is extremely important, and it is capable of inducing a helical structure in the peptide C-terminal region, while the Nterminal region contributes with the hydrophobic interactions needed to the peptide penetration in the phospholipid layers and to the disruption of them. Similarly, the Plantaricina149 antimicrobial activity has also proved to be a result of the interactions from the two regions of the molecule, and it was strongly affected by the removal or modification of the peptide N-terminal region. Promoting the deletion of this region has left the peptide only with a bacteriostatic action against Staphylococcus aureus and Pseudomonas aeruginosa, removing its bactericide ability.
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Etude du mécanisme d'interaction des peptides vecteurs riches en arginine avec des membranes lipidiques modèles. / Interaction mechanism study of arginine-rich cell-penetrating peptides with lipid membrane modelsJobin, Marie-Lise 30 September 2014 (has links)
Les peptides vecteurs riches en Arginine (Arg) ont la faculté de transporter des molécules à travers les membranes cellulaires, d'une manière récepteur- et énergie indépendante, sans toxicité envers la cellule et présentent ainsi un fort potentiel pour la libération de molécules thérapeutiques ou diagnostiques. La compréhension du mécanisme d'internalisation cellulaire et de l'interaction membranaire de ces peptides vecteurs est donc primordiale pour leur développement pharmaceutique. Dans cette étude, deux peptide svecteurs riches en Arg et dérivés de la pénétratine ont été étudiés : les peptides RW16(RRWRRWWRRWWRRWRR) et RW9 (RRWWRRWRR). Dans un premier temps,l'analyse biophysique complète de l'interaction peptide/lipide (P/L) a été réalisée pour le peptide RW16 et une interaction favorisée en présence de lipides anioniques a été révélée.Dans un second temps, des peptides dérivés de RW9 ont été synthétisés dans lesquels chaque tryptophane a été systématiquement remplacé par une phenylalanine. L'internalisation cellulaire et les interactions P/L de RW9 ont été étudiées, et l'importance de la position et du nombre de tryptophane dans la séquence peptidique a été mise en évidence. / Cell-penetrating peptides (CPPs) are able to efficiently transport cargos acrosscell membranes in a receptor- and energy-independent manner, without being cytotoxic to cells and thus present a great potential in drug delivery and diagnosis. The understanding of the cellular internalization and membrane interaction mechanisms is thus fundamental for their pharmaceutical development. In this study, two Arginine-rich CPPs derived from penetratin have been investigated: the peptides RW16 (RRWRRWWRRWWRRWRR) andRW9 (RRWWRRWRR). Firstly, a complete biophysical study of the peptide/lipid (P/L)interactions of RW16 has been accomplished and a preferential interaction for anionic lipids was demonstrated. Secondly, peptides derived from RW9 have been synthesized where tryptophan residues have been systematically replaced by phenylalanine. Cellular internalization and P/L interactions have been characterized, and the importance of the number and position of tryptophan has been highlighted.
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Plantaricina 149 e análogos: atividade antimicrobiana, estudos estruturais e mecanismos de ação / Plantaricin 149 and analogs: antimicrobial activity, structural studies and mechanisms of action.José Luiz de Souza Lopes 19 March 2010 (has links)
Peptídeos antimicrobianos são vistos como alternativas promissoras a serem empregadas pela iindústria farmacêutica no controle de infecções causadas por microrganismos, como também na indústria alimentícia, onde podem desempenhar papéis como conservantes naturais de alimentos. Plantaricina149 é um membro deste grupo, sendo composto por 22 resíduos de aminoácidos, com natureza catiônica e atividade inibitória sobre algumas bactérias patogênicas. Neste trabalho, foram sintetizados diferentes peptídeos análogos à Plantaricina149 para investigar suas ações sobre microrganismos (bactérias e fungos), a fim de correlacionar estes estudos com a ação lítica do peptídeo em modelos de membrana diversos (monocamadas e vesículas fosfolipídicas). A interação de Plantaricina149 com estes sistemas foi monitorada pelas espectroscopias de dicroísmo circular e fluorescência, ensaios de tensão superficial, calorimetria e ressonância plasmônica de superfície, e mostrou ser altamente específica para superfícies fosfolipídicas que apresentam densidade de cargas negativas, tais como a membrana celular de bactérias. A interação eletrostática inicial que se estabelece entre o peptídeo e os fosfolipídios é de extrema importância, sendo capaz de induzir uma estruturação helicoidal na região C-terminal do peptídeo, enquanto a região Nterminal contribui com as interações hidrofóbicas necessárias para a penetração do peptídeo nas camadas fosfolipídicas levando a ruptura das mesmas. De forma semelhante, a atividade antimicrobiana de Plantaricina149a (e alguns de seus análogos) também mostrou ser resultado das interações das duas regiões da molécula, e foi afetada com a retirada ou modificação da região N-terminal do peptídeo. Com a deleção desta região, o peptídeo passou a ter somente ação bacteriostática sobre Staphylococcus aureus e Pseudomonas aeruginosa, perdendo a capacidade bactericida. / Antimicrobial peptides are seen as promising alternatives to be employed in pharmaceutical industry for controlling infections caused by microorganisms, and also in food industry, where they can play roles as natural food preservatives. Plantaricina149 is a member of this group, constituted of 22 amino acid residues, cationic in nature and presenting inhibitory activity against some pathogenic bacteria. In this work, different Plantaricina149 analog peptides were synthesized to investigate their action against microorganisms (bacteria and fungi), with the aim of correlating these studies with the lytic action of the peptide on several membrane models (phospholipid monolayers and vesicles). The Plantaricina149 interaction with these systems was monitored by circular dichroism and fluorescence spectroscopies, surface tension assays, calorimetry and surface plasmon resonance, and showed to be highly specific to phospholipid surfaces that present negative charge density, such as the bacteria cell membrane. The initial peptide-phospholipids electrostatic interaction is extremely important, and it is capable of inducing a helical structure in the peptide C-terminal region, while the Nterminal region contributes with the hydrophobic interactions needed to the peptide penetration in the phospholipid layers and to the disruption of them. Similarly, the Plantaricina149 antimicrobial activity has also proved to be a result of the interactions from the two regions of the molecule, and it was strongly affected by the removal or modification of the peptide N-terminal region. Promoting the deletion of this region has left the peptide only with a bacteriostatic action against Staphylococcus aureus and Pseudomonas aeruginosa, removing its bactericide ability.
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Biological membrane interfaces involved in diseases : a biophysical studyLindström, Fredrick January 2006 (has links)
Interactions between peptides and biological lipid membranes play a crucial role in many cellular processes such as in the mechanism behind Alzheimer’s disease where amyloid-beta peptide (Abeta)is thought to be a key component. The initial step of binding between a surface active peptide and its target membrane or membrane receptor can involve a non specific electrostatic association where positively charged amino acid residues and a negatively charged membrane surface interact. Here, the use of high resolution MAS NMR provides a highly sensitive and non perturbing way of studying the electrostatic potential present at lipid membrane surfaces and the changes resulting from the association of peptides. The interaction between pharmacologically relevant peptides and lipid membranes can also involve incorporation of the peptide into the membrane core and by complementing the NMR approach with differential scanning calorimetry (DSC) the hydrophobic incorporation can be studied in a non invasive way. By using 14N MAS NMR on biological lipid systems for the first time, in addition to 31P, 2H NMR and differential scanning calorimetry (DSC), gives a full picture of the changes all along the phospholipid following interactions at the membrane interface region. Being able to monitor the full length of the phospholipid enables us to differentiate between interactions related to either membrane surface association or hydrophobic core incorporation. This approach was used to establish that the interaction between nociceptin and negatively charged lipid membranes is electrostatic and hence that nociceptin can initially associate with a membrane surface before binding to its receptor. Also, it was found that Abeta can interact with phospholipid membranes via two types of interactions with fundamentally adverse effects. The results reveal that Abeta can associate with the surface of a neuronal membrane promoting accelerated aggregation of the peptide leading to neuronal apoptotic cell death. Furthermore it is also shown that Abeta can anchor itself into the membrane and suppress the neurotoxic aggregation of Abeta.
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Biophysical investigations of the LAH4 family peptides : enhancer of gene delivery, from peptide-peptide interactions to peptide-membrane interactions / Etude biophysique de peptides de la famille du LAH4 : un amplificateur de systèmes de transport de gènes, de l’interaction peptide-peptide à l’interaction peptide-membraneWolf, Justine 20 September 2018 (has links)
Les peptides de la famille du LAH4 sont des peptides cationiques capables de se replier en hélice α amphiphile. Ces peptides sont riches en histidines ce qui permet de moduler les interactions de ces peptides de manière pH dépendante et dans une gamme physiologique. Leurs capacités à interagir et perturber les membranes ont été utilisées pour divers applications biologique, et notamment pour l'amélioration de systèmes de transport de gènes.Le travail de cette thèse a été divisé en trois parties dans le but de caractériser de manière biophysique les différentes interactions ayant lieu lors de la livraison du système de transport de gènes à l’intérieur d’une cellule. L’interaction peptide-peptide : avec l’étude de l’agrégation en fibrilles de la VF1 ; l’interaction peptide-membrane : avec l’effet du LAH4L1 en présence de membranes ; et l’interaction peptide-ADN : avec le suivit de l’interaction entre le LAH4L1 et de l'ADN. / The LAH4 family consists of cationic amphiphilic peptides with propensity to fold in α-helical secondary structures. They contain histidines allowing the modulation of their interactions in a pH dependent manner in the physiological range. In membranes, at neutral or acidic pH the peptide assumes a transmembrane or an in planar configuration, respectively.In the field of gene delivery systems, peptides like LAH4 are used. They are able to firstly interact with different cargoes in order to form stable complexes, then interact with the cell membrane, and finally, promote to escape from the endosome.This PhD has been divided into three parts in order to characterize, with biophysical methods, the interactions occurring during the delivery of these gene systems: peptide-peptide interactions with a focus on the study of VF1 fibre formation; peptide-membrane interactions: with the investigation of the effect of LAH4L1 in different membranes; and peptide-DNA interactions, where the interactions of LAH4L1 with a small DNA fragment were measured.
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