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HIV-1 Evasion of Human TRIM5α via Cyclophilin AKim, Kyusik 17 July 2020 (has links)
The abundant cellular protein Cyclophilin A (CypA) was found to bind to HIV-1 capsid (CA) in 1993. Since that time, several complementary methods, including disruption of the binding interface by cyclosporine A, CA mutants, and CypA mutants, have been used to demonstrate that CypA acts within human target cells to promote HIV-1 infection. In contrast, in cells from non-human primates, CypA in target cells decreases HIV-1 infectivity, and it does so by promoting TRIM5α-mediated restriction. Using human cancer cell lines and the genetic methods available at the time, attempts to obtain evidence that CypA inhibits HIV-1 restriction by the human TRIM5α ortholog, let alone that human TRIM5α restricts HIV-1, were unsuccessful.
Here we revisit the question of the mechanism by which CypA increases HIV-1 infectivity by exploiting lentiviral vectors optimized for primary human blood cells that serve as HIV-1 targets. Disruption of CA−CypA interaction is demonstrated to render HIV-1 vulnerable to endogenous human TRIM5α-mediated recognition and restriction, which occur prior to completion of reverse transcription. Identical findings were acquired with single-cycle vectors or with replication-competent viruses. Consistently, a previously identified, cyclosporine-resistant CA mutation A92E is also shown to confer resistance against restriction by human TRIM5α. Therefore, the results presented in this thesis reveal that HIV-1 exploits a host protein CypA bound to its CA to evade potent restriction by human TRIM5α. This finding not only answers a long-standing question regarding the role of CypA in HIV-1 infection, but also may reinvigorate the development of CypA inhibitors for treatment of HIV-1.
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Expedient synthesis of chiral poly-substituted morpholine and oxazepine derivatives for the preparation of cyclophilin A inhibitorsBilbeisi, Rana A., 1983- January 2008 (has links)
No description available.
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Aspectos bioquímico-estruturais do transportador de nucleotídeos de adenina, cardiolipinas e ciclofilina D na transição de permeabilidade mitocondrial induzida por Ca2+ / Structure-biochemical aspects of adenine nucleotide translocase, cardiolipin and ciclophilin D on Ca2+-induced mitochondrial permeability transitionPestana, Cezar Rangel 10 May 2010 (has links)
A oxidação do resíduo de cisteína 56 (ANT-cys56) do transportador de nucleotídeos de adenina (ANT) é descrita como evento crítico da Transição de Permeabilidade Mitocondrial (TPM), fenômeno caracterizado pela sensibilidade ao fármaco imunossupressor ciclosporina A (CsA), responsável pela ligação e inibição do componente promotor da abertura do Poro de Transição de Permeabilidade (PTP), a enzima peptidil-prolil-cis trans isomerase (cyp D). Aspectos bioquímico-estruturais do ANT, das cardiolipinas (CDL) que envolvem o transportador e da cyp D na TPM foram avaliados por meio de ensaios turbidimétricos de inchamento mitocondrial e estado conformacional do ANT em mitocôndrias isoladas de fígado de rato, associados a abordagens de química computacional para análises de campos de interação molecular (MIF) e dinâmica molecular (MD), visando a predição de eventos envolvidos na abertura do PTP. As análises computacionais revelaram aumento da mobilidade relativa do ANT-cys56, como resultado da interação preferencial do Ca2+ com a molécula de CDL ligada à hélice 4 do transportador, enquanto que a inversão da configuração do resíduo de prolina do ANT (ANT-pro61) potencializou o efeito induzido por Ca2+. A presença de ADP no interior do ANT preveniu o aumento da mobilidade relativa do ANT-cys56 promovida pelo Ca2+, enquanto que a inversão da configuração do ANT-pro61, de trans para cis, potencializou o efeito promovido pelo Ca2+ na mobilidade relativa do ANT-cys56, de forma insensível ao nucleotídeo. Os ensaios com mitocôndrias isoladas demonstraram que o Ca2+ induz a conformação c do ANT e promove abertura do PTP, de forma sensível à CsA e ADP. A presença de cyp D estabilizou a conformação c do ANT induzida por Ca2+, sendo que Atractilosídeo (ATR) tornou o efeito parcialmente insensível aos inibidores da TPM. Os resultados sugerem que a abertura do PTP induzida por Ca2+ envolve a mudança conformacional do ANT para o estado c, cuja estabilização é obtida pela cyp D na função de inversão do ANT-pro61, com base na avaliação da mobilidade relativa do ANT-cys56 parcialmente sensível ao ADP. / Oxidation of the Adenine Nucleotide Translocase (ANT) cysteine residue 56 (ANT-cys56) is potentially involved in Ca2+-induced Mitochondrial Permeability Transition (MPT), a process which is prevented by cyclosporine A (CsA), due to its inhibition of Permeability Transition Pore (PTP) opener component, the peptidyl-prolyl cis-trans isomerase cyclophylin D (cyp D). The main aspects of ANT, cardiolipins (CDL) and cyp D on Ca2+-induced PTP opening were addressed by employing light scattering techniques in isolated rat liver mitochondria to assess both ANT conformational change and mitochondrial swelling in association with computational chemistry analysis of Molecular Interaction Fields (MIF) and Molecular Dynamics (MD) for PTP events predictions. Computational analysis revealed that Ca2+ interacts preferentially with the ANT surrounding CDL bound to the H4 helix of the carrier and weakens the CDL/ANT interactions accounting for the ADP-sensitive increase of ANT-cys56 relative mobility while ANT-pro61 cis to trans configuration inversion intensified the Ca2+ effect in a ADP-insensitive way. The ANT conformation and mitochondrial swelling analyses demonstrated that Ca2+ induces conformation c of ANT and opens PTP in a CsA- and ADP-sensitive way. Cyp D stabilizes Ca2+-induced ANT conformation c, whereas ATR renders a PTP opening less sensitive to the inhibition by CsA or ADP. The results suggest that Ca2+-induced PTP opening involves ANT conformation c change supported by a cyp D-induced trans to cys ANT-pro61 configuration inversion based on the relative mobility of ANT-cys56, in a ADP-sensitive manner.
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Importance of intracellular Mitochondria-Associated endoplasmic reticulum Membranes (MAM) in insulin-resistance / Importance des interactions intracellulaires entre la mitochondrie et le réticulum endoplasmique dans l'insulino-résistanceTubbs, Emily 17 October 2014 (has links)
Les mitochondries et le réticulum endoplasmique (RE) interagissent au niveau de points de contacts appelés « Mitochondria-Associated ER Membranes » (MAM), afin d'échanger du Ca2+ via le complexe TP3Rl/Grp75/VDACl et maintenir l'homéostasie énergétique. Bien que des dysfonctions mitochondriales, un stress du RE et des altérations de l'homéostasie du Ca2+ participent au développement de l'insulino-résistance, on ne sait pas si ce sont des facteurs indépendants ou s'ils sont inter-reliés par une altération des MAM. Mes travaux de thèse ont permis de mettre en évidence un nouveau rôle des MAM dans l'insulino-résistance hépatique. J'ai mis au point et validé la technique d'in situ PLA pour visualiser et quantifier les interactions mitochondrie-RE dans les cellules. J'ai montré que l'intégrité des MAM était nécessaire pour la signalisation de l'insuline dans le foie, et qu'un défaut d'intégrité des MAM était impliqué dans l'insulino-résistance hépatique. Des données préliminaires suggèrent qu'une altération des MAM est également associée à l'insulino-résistance musculaire. J'ai ensuite mis en évidence la présence de la protéine kinase B, une protéine clé de la signalisation de l'insuline, dans les MAM, et démontré que sa phosphorylation par l'insuline est altérée dans cette fraction dans le foie de souris diabétique. Enfin, j'ai participé à la mise en évidence l) de la présence de la cyclophilin D à l'interface des MAM régulant les échanges calciques entre les deux organites dans les cardiomyocytes et les hépatocytes, et 2) d'une régulation des MAM par le glucose dans le foie qui permet un contrôle de la dynamique et de la fonction mitochondriale au cours des transitions nutritionnelles. Par conséquent, mes travaux ont permis d'améliorer les connaissances actuelles sur les partenaires, la fonction et la régulation des MAM et de dévoiler les MAM comme une nouvelle cible pour moduler la signalisation de l'insuline et le métabolisme hépatique / Mitochondria-associated endoplasmic reticulum membranes (MAM) are functional domains between both organelles involved in Ca2+ exchange, through the voltage-dependent anion channel (VDAC)-1/glucose regulated protein 75 (Grp75)/inositol 1,4,5-triphosphate receptor (TP3R)-1 complex, and regulating energy metabolism. Whereas mitochondrial dysfunction, ER stress, and altered Ca2+ homeostasis are associated with altered insulin signalling, the implication of MAM dysfunctions in insulin resistance is unknown. During my PhD, my work has underlined a new role of MAM in hepatic insulin- resistance. T have developed a quantitative method called in situ Proximity Ligation Assay to visualise and quantify the interactions between ER and mitochondria. T have shown that MAM integrity is required for insulin signalling and that disruption of MAM is implicated in hepatic insulin resistance. Preliminary data also suggest that MAM alterations are also associated with muscle insulin resistance. T have also identified the presence of the protein kinase B (PKB), a key protein involved in metabolic effects of insulin, at the MAM interface, and demonstrated that its phosphorylation by insulin is altered in this fraction in liver of diabetic mice. Lastly, T have also participated to the identification of: 1) the presence of cyclophilin D (CypD) at MAM interface which regulates calcium transfer from ER to mitochondria in both cardiomyocytes and hepatocytes, and 2) a regulation of MAM by glucose in liver, which is involved in the regulation of mitochondria dynamics and function during nutritional transitions. Consequently, my work improved the knowledge on the composition, function and regulation of MAM, and highlighted MAM as a potential new target for the modulation of hepatic insulin action and metabolism
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Exploring the cellular mechanisms of Cnidarian bleaching in the sea anemone Aiptasia pallidaPerez, Santiago 03 April 2007 (has links)
Many members of the Phylum Cnidaria are mutualistic with unicellular
dinoflagellates belonging to the genus Symbiodinium. Corals are the most widely
recognized example of these associations due to their key ecological importance in
coral reef ecosystems where they serve as the structural and trophic foundation of
these rich ecosystems. Coral reefs are severely threatened by human activities worldwide
and are at great risk from global climate change, in particular the increase in seasurface
temperatures. Detailed knowledge of how corals respond to stress is scarce.
The most serious and immediate response of corals to environmental stress is a
process referred to as coral bleaching (a.k.a. cnidarian bleaching). Nevertheless, the
cellular and molecular processes by which elevated temperatures elicit the bleaching
response are poorly understood. This dissertation deals with this important question
by describing two mediators of cnidarian bleaching in the model symbiotic tropical
sea anemone Aiptasia pallida (Verril), namely nitric oxide and cyclophilin.
After an introduction to the topic of cnidarian-algal symbioses and cnidarian
bleaching (Chapter 1), I present results from a study describing the involvement of
nitric oxide (NO) in the anemone A. pallida (Chapter 2). Elevated temperature as well
as oxidative stress induces production of NO and exposure of A. pallida to NO induces
bleaching at non-stressful temperatures. Co-incubation with an NO scavenger
suppresses bleaching. I propose that the host up-regulates NO production in response
to elevated oxidative stress and that this situation leads to cytotoxicity and bleaching.
Chapter 3 examines the role of cyclophilin from A. pallida in the regulation of
the symbiosis. Cyclophilins belong to a highly conserved family peptydyl-prolyl cistrans
isomerases (PPIases). Incubation of A. pallida with cyclosporin A (CsA), a
potent inhibitor of cyclophilin resulted in bleaching and a decrease in tolerance to
elevated temperatures. Protein extracts from A. pallida exhibited CsA-sensitive
PPIase activity. Laser scanning confocal microscopy using superoxide and nitric
oxide-sensitive fluorescent dyes on live A. pallida revealed that CsA strongly induced
the production reactive oxygen species as well as NO. We tested weather the CsAsensitive
isomerase activity is important for maintaining the activity of the antioxidant
enzyme superoxide dismutase (SOD). SOD activity of protein extracts was
not affected by pre-incubation with CsA in vitro. In Chapter 4 I review what is known
about the molecular and cellular mechanisms of bleaching and describe a model of
bleaching based on the results presented herein as well as studies of non-cnidarian
models. / Graduation date: 2007
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Aspectos bioquímico-estruturais do transportador de nucleotídeos de adenina, cardiolipinas e ciclofilina D na transição de permeabilidade mitocondrial induzida por Ca2+ / Structure-biochemical aspects of adenine nucleotide translocase, cardiolipin and ciclophilin D on Ca2+-induced mitochondrial permeability transitionCezar Rangel Pestana 10 May 2010 (has links)
A oxidação do resíduo de cisteína 56 (ANT-cys56) do transportador de nucleotídeos de adenina (ANT) é descrita como evento crítico da Transição de Permeabilidade Mitocondrial (TPM), fenômeno caracterizado pela sensibilidade ao fármaco imunossupressor ciclosporina A (CsA), responsável pela ligação e inibição do componente promotor da abertura do Poro de Transição de Permeabilidade (PTP), a enzima peptidil-prolil-cis trans isomerase (cyp D). Aspectos bioquímico-estruturais do ANT, das cardiolipinas (CDL) que envolvem o transportador e da cyp D na TPM foram avaliados por meio de ensaios turbidimétricos de inchamento mitocondrial e estado conformacional do ANT em mitocôndrias isoladas de fígado de rato, associados a abordagens de química computacional para análises de campos de interação molecular (MIF) e dinâmica molecular (MD), visando a predição de eventos envolvidos na abertura do PTP. As análises computacionais revelaram aumento da mobilidade relativa do ANT-cys56, como resultado da interação preferencial do Ca2+ com a molécula de CDL ligada à hélice 4 do transportador, enquanto que a inversão da configuração do resíduo de prolina do ANT (ANT-pro61) potencializou o efeito induzido por Ca2+. A presença de ADP no interior do ANT preveniu o aumento da mobilidade relativa do ANT-cys56 promovida pelo Ca2+, enquanto que a inversão da configuração do ANT-pro61, de trans para cis, potencializou o efeito promovido pelo Ca2+ na mobilidade relativa do ANT-cys56, de forma insensível ao nucleotídeo. Os ensaios com mitocôndrias isoladas demonstraram que o Ca2+ induz a conformação c do ANT e promove abertura do PTP, de forma sensível à CsA e ADP. A presença de cyp D estabilizou a conformação c do ANT induzida por Ca2+, sendo que Atractilosídeo (ATR) tornou o efeito parcialmente insensível aos inibidores da TPM. Os resultados sugerem que a abertura do PTP induzida por Ca2+ envolve a mudança conformacional do ANT para o estado c, cuja estabilização é obtida pela cyp D na função de inversão do ANT-pro61, com base na avaliação da mobilidade relativa do ANT-cys56 parcialmente sensível ao ADP. / Oxidation of the Adenine Nucleotide Translocase (ANT) cysteine residue 56 (ANT-cys56) is potentially involved in Ca2+-induced Mitochondrial Permeability Transition (MPT), a process which is prevented by cyclosporine A (CsA), due to its inhibition of Permeability Transition Pore (PTP) opener component, the peptidyl-prolyl cis-trans isomerase cyclophylin D (cyp D). The main aspects of ANT, cardiolipins (CDL) and cyp D on Ca2+-induced PTP opening were addressed by employing light scattering techniques in isolated rat liver mitochondria to assess both ANT conformational change and mitochondrial swelling in association with computational chemistry analysis of Molecular Interaction Fields (MIF) and Molecular Dynamics (MD) for PTP events predictions. Computational analysis revealed that Ca2+ interacts preferentially with the ANT surrounding CDL bound to the H4 helix of the carrier and weakens the CDL/ANT interactions accounting for the ADP-sensitive increase of ANT-cys56 relative mobility while ANT-pro61 cis to trans configuration inversion intensified the Ca2+ effect in a ADP-insensitive way. The ANT conformation and mitochondrial swelling analyses demonstrated that Ca2+ induces conformation c of ANT and opens PTP in a CsA- and ADP-sensitive way. Cyp D stabilizes Ca2+-induced ANT conformation c, whereas ATR renders a PTP opening less sensitive to the inhibition by CsA or ADP. The results suggest that Ca2+-induced PTP opening involves ANT conformation c change supported by a cyp D-induced trans to cys ANT-pro61 configuration inversion based on the relative mobility of ANT-cys56, in a ADP-sensitive manner.
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Skin from horses with hereditary equine regional dermal asthenia (HERDA) contains collagen crosslinking patterns that are associated with reduced tensile strengthHill, Ashley Arwen 07 August 2010 (has links)
Hereditary equine regional dermal asthenia (HERDA) is a recessive connective tissue disorder of Quarter Horse lineages. This study correlates previously identified decreases in skin tensile strength in HERDA with abnormal dermal collagen cross linking patterns that are also identified in urine from HERDA horses. Dermal collagen from HERDA horses has significantly less pyridinoline and significantly more deoxypyridinoline than control or carriers. Concentrations of hydroxylysine, the rate limiting substrate for these crosslinks were significantly lower in HERDA versus control and carriers. These characteristics of HERDA skin parallel humans with a similar syndrome of skin fragility, Ehlers Danlos Syndrome TypeVIA. This is the first biochemical evidence explaining the clinical skin fragility that characterizes HERDA and suggests that altered collagen lysine metabolism may be physiologically relevant to the clinical manifestation of HERDA. Evaluations of mature scars indicate that lesion and nonlesioned skin should not be viewed as biologically equivalent in HERDA investigations.
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Régulation du pore de transition de perméabilité mitochondriale dans la cardioprotection : interactions entre la cyclophiline D, le complexe I et le calcium / Regulation of mitochondrial permeability transition pore in cardioprotection : interactions between cyclophilin D, complex I and calciumTeixeira, Geoffrey 21 November 2012 (has links)
L’I/R et la cardioprotection par PreC et PostC impactent la fonction mitochondriale et plus précisément le mPTP. Le mPTP est non seulement modulé par des protéines qui participent à sa formation comme la CypD mais aussi par l’environnement cellulaire. Le but de ma thèse a été d’étudier la régulation du mPTP par la CypD, le complexe I et le Ca2+ durant l’I/R et la cardioprotection. Nos conclusions sont : 1. Le complexe I de la chaîne respiratoire mitochondriale régule l’ouverture du mPTP et cela de façon CypD-dépendante. 2. Le PostC est un inhibiteur du complexe I, l’Iso, est le seul PostC efficace chez le rat in vivo. 3. L’inhibition pharmacologique ou génétique de la CypD cardioprotège en modulant l’ouverture du mPTP et l’homéostasie calcique. 4. La CypD a un nouveau rôle dans la cardioprotection, indépendamment de son action sur le mPTP. En effet, elle module le transfert calcique au niveau des MAM et plus précisément le transfert de Ca2+ entre les RS et la mitochondrie. Son inhibition prévient la surcharge calcique mitochondriale intervenant lors de l’I/R. L’ensemble de ces résultats nous permet de conclure que le mPTP est régulé par de nombreux facteurs interconnectés. Le Ca2+ est l’effecteur principal de l’ouverture du mPTP. La CypD a une action Ca2+ dépendante et module l’homéostasie calcique au niveau des MAM. Le complexe I régule l’ouverture du mPTP de façon CypD dépendante. Enfin les fonctions mitochondriales cardioprotecteurs mPTP-dépendants englobe la CypD, le Ca2+, le complexe I et les fonctions mitochondriales. Cette vision plus large et intégrée de la régulation du mPTP pourra donner des pistes plus efficaces dans le développement de traitements pharmacologiques cardioprotecteurs / Reperfusion of the heart after an ischemic event leads to the opening of a nonspecific pore in the inner mitochondrial membrane, the mitochondrial permeability transition pore (mPTP). Inhibition of mPTP opening is an effective strategy to prevent cardiomyocyte death. For example, inhibition of mPTP opening via ischaemic preconditioning (PreC) and post-conditioning (PostC) decreased the myocardial infarct size after ischemia–reperfusion. Although the molecular composition of the mPTP remains unclear, the matrix protein cyclophilin-D (CypD) is the best defined regulatory component of mPTP. In this thesis, we demonstrated that Complex I of the respiratory mitochondrial chain also regulates mPTP in a CypD-dependent manner. We also proved that inhibition of Complex I by isoflurane prevents lethal reperfusion injury in an in vivo rat model of ischemia-reperfusion. Finally, we proved that cardioprotective inhibition of CypD modulates calcium homeostasis and fluxes between mitochondria and sarcoplasmic reticulum. In summary, our results suggest that mPTP is regulated by several interconnected factors like calcium, CypD, complex I and mitochondrial functions
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EXPLORING THE MOLECULAR MECHANISM OF ROOT-MEDIATED RESPONSES TO <i>RALSTONIA</i>Katherine Rivera-Zuluaga (17552421) 06 December 2023 (has links)
<p dir="ltr">Bacterial Wilt, caused by <i>Ralstonia solanacearum</i>, is among the most devastating plant diseases in the world. This pathogen causes significant loss in crops such as tobacco, potato, and tomato. <i>R. solanacearum</i> root infection and xylem colonization determine disease outcome. To date, little is known about the defense mechanism mediated by roots to prevent <i>R. solanacearum</i> vascular colonization during the initial infection stages. Plant early responses are important since they may impact disease outcomes<i>.</i><i> </i>Here, we report the formation of root hairs and primary root growth inhibition in tomato seedlings as <i>Ralstonia</i>-induced phenotypes that depend on tomato genotype and <i>Ralstonia</i> species. The <i>Ralstonia</i>-induced root phenotypes are independent of a functional type III secretion system and exopolysaccharide production (EPS). We also found that <i>R. solanacearum</i><i> </i>K60 infection increased auxin levels throughout the root meristem in wilt-susceptible tomato roots. Our data suggest proper auxin signaling and transport are important for susceptibility to <i>R. solanacearum</i> K60. Blocking auxin transport pharmacologically or genetically led to fewer wilting symptoms, suggesting that auxin is important during early infection stages and disease outcomes in tomato. We previously found that a tomato mutant defective in auxin transport and signaling, known as <i>diageotropica</i> (<i>dgt</i>), has enhanced resistance to <i>R. solanacearum</i> K60. We characterized the resistant response in the <i>dgt</i> mutant, and we found that the resistant response in the <i>dgt</i> mutant may be due to increased lignin content preventing pathogen vasculature colonization. <i>DGT</i> encodes a cyclophilin protein that regulates auxin transport and signaling. Mutations in the cyclophilin DGT promote resistance to <i>R. solanacearum</i> K60. DGT has been reported to regulate auxin transport and signaling. However, the molecular mechanism regarding how DGT mediates these processes is still unknown. We used Yeast Two-Hybrid to identify candidate protein interactors, and we found that SlbZIP1/SlbZIP29, Sl14-3-3, and SlMYB110 may interact with DGT to regulate both development and defense responses. Understanding the role of DGT, auxin, and lignin in defense responses to <i>R. solanacearum</i> K60 in tomato is necessary for Solanaceae crop improvement.</p>
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Investigating protein-protein interactions in order to develop novel therapeutics for the treatment of Alzheimer's diseaseAitken, Laura January 2013 (has links)
Alzheimer's disease (AD) accounts for around two thirds of all dementia cases and an increase in life expectancy of the population has resulted in a substantial increase in dementia cases and with that a rise in AD. AD is a debilitating and ultimately fatal neurodegenerative disorder of the elderly, and despite being identified over a century ago, the current treatments do not treat the underlying causes behind the disease, instead they help to mask the symptoms of the disease and prolong the brain's remaining function. It is therefore vital that an effective, disease modifying treatment for this disease is established as soon as possible. Soluble intracellular forms of amyloid β (peptide Aβ), a hallmark of AD have been identified and intracellular targets of Aβ are being investigated as potential drug targets for the disease. Two key intracellular, mitochondrial proteins investigated as potential drug targets: amyloid binding alcohol dehydrogenase (ABAD) and cyclophilin D (CypD) are the focus of the work reported in this thesis. To begin identifying potential inhibitors of the ABAD-Aβ interaction, a two-pronged approach was taken. Firstly, a series of analogues based on a known inhibitor of the interaction were tested using a variety of biophysical assays, for their therapeutic affect on the interaction, and secondly a fragment based screening approach was used to identify new small molecule binding partners of ABAD which could potentially be modified to produced inhibitors of the ABAD-Aβ interaction. Three different CypD constructs have been successfully expressed and purified, and taken into crystal trials. It is hoped that these constructs can be used to significantly aid the progress of identifying any potential inhibitors and binding partners of CypD that may produce therapeutic effects, and in the future could lead to the identification of an effective disease modifying drug in the treatment of AD. The work reported in this thesis has built upon previously reported findings and the groundwork has also been established for several in vitro biophysical assays, these include for example: measuring ABAD enzyme activity, and the novel morphology specific Aβ aggregation assay, which can be used as screening tools to help identify potential inhibitors of these interactions. Both the ABAD-Aβ interaction, and the blockade of CypD are known to be drug targets in the treatment of AD, and by elucidating the molecular mechanisms behind these interactions, through implementing biophysical assays, this will help in the identification and design of potential new therapeutic agents for the treatment of AD.
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