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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
181

Structural and Biophysical Characterisation of Denatured States and Reversible Unfolding of Sensory Rhodopsin II

Tan, Yi Lei January 2019 (has links)
Our understanding of the folding of membrane proteins lags behind that of soluble proteins due to the challenges posed by the exposure of hydrophobic regions during in vitro chemical denaturation and refolding experiments. While different folding models are accepted for soluble proteins, only the two-stage model and the long-range interactions model have been proposed so far for helical membrane proteins. To address our knowledge gap on how different membrane proteins traverse their folding landscapes, Chapter 2 investigates the structural features of SDS-denatured states and the kinetics for reversible unfolding of sensory rhodopsin II (pSRII), a retinal-binding photophobic receptor from Natronomonas pharaonis. pSRII is difficult to denature, and only SDS can dislodge the retinal chromophore without rapid aggregation. Even in 30% SDS (0.998 $\mathit{\Chi}_{SDS}$), pSRII retains the equivalent of six out of seven transmembrane helices, while the retinal binding pocket is disrupted, with transmembrane residues becoming more solvent-exposed. Folding of pSRII from an SDS-denatured state harbouring a covalently-bound retinal chromophore shows deviations from an apparent two-state behaviour. SDS denaturation to form the sensory opsin apo-protein is reversible. This chapter establishes pSRII as a new model protein which is suitable for membrane protein folding studies and has a unique folding mechanism that differs from those of bacteriorhodopsin and bovine rhodopsin. In Chapter 3, SDS-denatured pSRII, acid-denatured pSRII and sensory opsin obtained by hydroxylamine-mediated bleaching of pSRII were characterised by solution state NMR. 1D $^1$H and $^{19}$F NMR were first used to characterise global changes in backbone amide protons and tryptophan side-chains. Residue-specific changes in backbone amide chemical shifts and peak intensities in 2D [$^1$H,$^{15}$N]-correlation spectra were analysed. While only small changes in the chemical environment of backbone amides were detected, changes in backbone amide dynamics were identified as an important feature of SDS- and acid-denatured pSRII and sensory opsin. $^{15}$N relaxation experiments were performed to study the backbone amide dynamics of SDS-denatured pSRII, reflecting motions on different timescales, including fast fluctuations of NH bond vectors on the ps-ns timescale and the lack of exchange contributions on the µs timescale. These studies shed insight on differences in the unfolding pathways under different denaturing conditions and the crucial role of the retinal chromophore in governing the structural integrity and dynamics of the pSRII helical bundle. Hydrogen bonds play fundamental roles in stabilising protein secondary and tertiary structure, and regulating protein function. Successful detection of hydrogen bonds in denatured states and during protein folding would contribute towards our understanding on the unfolding and folding pathways of the protein. Previous studies have demonstrated residue-specific detection of stable and transient hydrogen bonds in small globular proteins by measuring $^1{\it J}_{NH}$ scalar coupling constants using NMR. In Chapter 4, different methods for measuring $^1{\it J}_{NH}$ scalar coupling were explored using RalA, a small GTPase with a mixed alpha/beta fold, as proof-of-concept. Detection of hydrogen bonds was then attempted with OmpX, a beta-barrel membrane protein, both in its folded state in DPC micelles and in the urea-denatured state. While $^1{\it J}_{NH}$ measurement holds promise for studying hydrogen bond formation, further optimisation of NMR experiments and utilisation of perdeuterated samples are required to improve the precision of such measurements in large detergent-membrane protein complexes. Naturally occurring split inteins can mediate spontaneous trans-splicing both in vivo and in vitro. Previous studies have demonstrated successful assembly of proteorhodopsin from two separate fragments consisting of helices A-B and helices C-G via a splicing site in the BC loop. To complement the in vitro unfolding/folding studies, pSRII assembly in vivo was attempted by introducing a splicing site in the loop region of the beta-hairpin constituting the BC loop of pSRII. The expression conditions for the N- and C-terminal pSRII-intein segments were optimised, and the two segments co-expressed. However, the native chromophore was not observed. Further optimisation is required for successful in vivo trans-splicing of pSRII and application of this approach towards understanding the roles of helices and loops in the folding of pSRII.
182

Structure And Dynamics Of Constrained Water : Microscopic Study Of Macromolecular Hydration Using Computer Simulations

Pal, Subrata 02 1900 (has links)
The thesis, which contains nine chapters, reports extensive large scale atomistic molecular dynamics (MD) simulation studies of water structure and dynamics at the surface of an anionic micelle, hydration layer of two proteins, and in the grooves of a 38-base pairs long DNA. Understanding the structure and dynamics of water molecules at the surfaces of self-organized assemblies and complex biological macromolecules has become a subject of intense research in recent times. Chapter 1 contains a brief overview of the biomolecular hydration dynamics. Relevant experimental, computational, and theoretical studies of biomolecular hydration and the time scales associated with the water dynamics are discussed. In Chapters 2 and 3, the structure, environment, energetics, and dynamics of constrained water molecules in the aqueous anionic micelle of cesium perfluorooctanoate (CsPFO) have been studied using large scale atomistic molecular dynamics simulations. Based on the number of hydrogen bond (HB) that interfacial water molecule makes with the polar head group (PHG) oxygen of the micelle, we find the existence of three kinds of water at the interface. We introduce a nomenclature to identify the species as IBW2 (form two HBs with two different PHG), IBW1 (form one HB with PHG), and IFW (no HB with PHG). Despite of possessing two strong w-PHG bonds, the concentration of the IBW2 species is rather low due to entropic effect. The ion solvation dynamics study at the interface shows the presence of a slow component, with a relaxation time 1-2 order of magnitude slower than that in the corresponding bulk solvent in agreement with the experimental results. Both the translational and orientational dynamics of the water molecules near the micellar surface is found to be much slower than those in the bulk. The HB between the PHG of the micelle and the water molecule has almost 13 times longer life time than that in the bulk between two tagged water molecules. In Chapter 4, we present results of extensive atomistic MD simulation studies of the structure and dynamics of aqueous protein solution of the toxic domain of Enterotoxin (1ETN) and the chicken villin headpiece sub-domain containing 36 amino acid residues (HP-36). Reduced water structure and the faster water dynamics around the active site of these proteins have been observed which may have biological significance. Chapter 5 presents an extensive atomistic molecular dynamics simulations study of water dynamics in the hydration layer of a 38 base long hydrated DNA duplex. The computed rotational time correlation function (TCF) of the minor groove water dipoles is found to be markedly non-exponential with a slow component at long time. The constrained water molecule is also found to exhibit anisotropic diffusion in both the major and minor grooves. At short-to-intermediate times, translational motion of water molecules in minor groove is sub-diffusive. Chapter 6 presents the study of water entropy in both the grooves DNA. The average values of the entropy of water at 300K in both the grooves of DNA are found to be significantly lower than that in bulk water. We propose that the configurational entropy of water in the grooves can be used as a measure of the mobility (or micro viscosity) of water molecules in a given domain. In Chapter 7, we study the specific DNA base-water hydrogen bond lifetime (HBLT) dynamics at the major and the minor grooves of a hydrated duplex. The base-water HBLT correlation functions are in general multi-exponential and the average lifetime depends significantly on the specificity of the DNA sequence. The average HBLT is longer in the minor groove than that in the major groove by almost a factor of 2. Chapter 8 presents the solvation dynamics of constituent bases of aqueous DNA duplex. The solvation TCFs of the four individual bases display highly non-exponential decay with time. An interesting negative cross-correlation between water and counterions is observed which makes an important contribution to relaxation at intermediate to longer times. In the concluding note, Chapter 9 presents a brief summary of the outcome of the thesis and suggests several relevant problems that may prove w orthwhile to be addressed in future
183

Μεταβολομική ανάλυση κυττάρων HeLa μετά από υπερέκφραση της πρωτεΐνης DGCR14, ενός παράγοντα που σχετίζεται με το σωματίδιο συναρμογής (spliceosome)

Καυκιά, Ελένη 02 March 2015 (has links)
Στην μετα-γονιδιωματική εποχή, την εποχή της συστημικής βιολογίας, η κατανόηση της πολυπλοκότητας της κυτταρικής φυσιολογίας απαιτεί την ανάλυση της δυναμικής των δικτύων βιομοριακών αλληλεπιδράσεων σε όλα τα μοριακά επίπεδα κυτταρικής λειτουργίας. Με τη σειρά της, η λειτουργική γονιδιωματική, ένας θεμελιώδης λίθος της συστημικής βιολογίας, στοχεύει στον πολυδιάστατο χαρακτηρισμό ενός γονιδίου, συνδυάζοντας δεδομένα από τις τεχνολογίες υψηλής απόδοσης. Είναι αυτή ακριβώς η ενοποίηση όλων των μοριακών προτύπων για ένα διαταραγμένο βιολογικό σύστημα που μπορεί να δώσει πληροφορίες αναφορικά με την λειτουργία ενός αγνώστου γονιδίου. Στο πλαίσιο αυτό, η παρούσα Διπλωματική Εργασία αποτελεί μέρος της ολιστικής λειτουργικής ανάλυσης δύο αλληλεπιδρώντων, αγνώστου βιολογικού ρόλου, πρωτεϊνών, της DGCR14 και της FRA10AC1, οι οποίες έχουν απομονωθεί ως συστατικά του σωματιδίου συναρμογής και έχουν συσχετιστεί με νευρολογικές ασθένειες. Η παρούσα εργασία επικεντρώνεται στην μεταβολομική μελέτη των μοριακών επιπτώσεων της υπερέκφρασης της DGCR14 σε ένα ανθρώπινο κυτταρικό μοντέλο, τα κύτταρα HeLa, με την χρήση της αέριας χρωματογραφίας - φασματομετρία μάζας. Ωστόσο, για να επιτευχθεί αυτό, θέματα σχετικά με τις δυνατότητες ποσοτικοποίησης των πολυβηματικών ομικών αναλύσεων έπρεπε να επιλυθούν. Μια σημαντική παράμετρος αφορά στην γρήγορη αδρανοποίηση των ενζυματικών διεργασιών έτσι ώστε οι αποκτηθέντες μετρήσεις να αντικατοπτρίζουν την πραγματική κυτταρική φυσιολογία. Για τον σκοπό αυτό, ο πειραματικός σχεδιασμός πρέπει να τροποποιείται κατάλληλα έτσι ώστε οποιεσδήποτε απαιτούμενες προ-αναλυτικές διαδικασίες χειρισμού των κυττάρων να έχουν ελάχιστη επίδραση στην φυσιολογία τους. Μελετήσαμε συνεπώς την επίδραση τεσσάρων πρωτοκόλλων συλλογής προσκολλημένων κυττάρων και δύο διαφορετικών διαλυμάτων έκπλυσης στο μεταβολικό πρότυπο κυττάρων HeLa. Τα μεταβολομικά δεδομένα αξιολογήθηκαν στο πλαίσιο της καρκινικής μεταβολικής φυσιολογίας και το πρωτόκολλο με την ελάχιστη δυνατή επίδραση στην κυτταρική φυσιολογία καθορίστηκε. Μεταξύ των αποτελεσμάτων αυτής της μελέτης, πολύτιμες πληροφορίες σχετικά με την μεταβολική φυσιολογία των αθανατοποιημένων κυτταρικών σειρών προέκυψαν, οι οποίες ενίσχυσαν σημαντικά την υπάρχουσα γνώση γύρω από τον καρκινικό μεταβολισμό, σε σταθερές ή μεταβαλλόμενες περιβαλλοντικές συνθήκες. Επακόλουθα, η βελτιστοποίηση της διαδικασίας συλλογής είχε ως αποτέλεσμα την δημιουργία ενός αντιπροσωπευτικού μεταβολικού προτύπου κυττάρων HeLa πάνω στο οποίο πραγματοποιήθηκε η αξιολόγηση της υπερέκφρασης της πρωτεΐνης DGCR14 χωρίς να επισκιάζεται από πειραματικές αποκλίσεις εισαγόμενες από την διαδικασία χειρισμού των κυττάρων. Αναφορικά με τα κύτταρα που υπερεκφράζουν την DGCR14, η μεταβολομική ανάλυση εντόπισε μια αλλαγή φυσιολογίας συνδεόμενη με συγκεκριμένα μεταβολικά μονοπάτια τα οποία υποδηλώνουν έντονο μεταβολικό στρες. Για να διερευνήσουμε την συσχέτιση της υπερέκφρασης της DGCR14 με τον παραπάνω μεταβολικό φαινότυπο, χρησιμοποιήσαμε το ανακατασκευασμένο δίκτυο πρωτεϊνικών αλληλεπιδράσεων του σωματιδίου συναρμογής στον άνθρωπο και το δίκτυο πρωτεϊνικών αλληλεπιδράσεων στον άνθρωπο από την μετα-βάση δεδομένων PICKLE, προκειμένου να αντλήσουμε επιπλέον πληροφορίες για τον ρόλο της DGCR14 βάσει της θέσης της σε σχέση με άλλους κόμβους και υπερ-κόμβους. Μια πιθανή λειτουργική συσχέτιση της DGCR14 με αυτοφαγικούς και λυσοσωμικούς μηχανισμούς βρέθηκε, η οποία θα αξιολογηθεί και μελλοντικά μέσω της ανάλυσης, ξεχωριστά και συνδυαστικά, των μοριακών συνεπειών της υπερ- και υπο-έκφρασης σε όλα τα μοριακά επίπεδα κυτταρικής λειτουργίας. / In the post-genomic, systems biology era, developing a systems level understanding of a physiological process requires the analysis of biomolecular network dynamics at all molecular levels of cellular function. Likewise, functional genomics, an essential foundation of systems biology research, aims to define and analyze gene function at a global level by integrating data obtained from multiple high-throughput technologies. It is the integration of all the molecular profiles for a systematically perturbed system that can provide insight about the function of unknown genes. Along these lines, the present study is part of the systematic functional analysis of two interacting, but yet of unknown biological role, spliceosomal proteins, DGCR14 and FRA10AC1, that have both been implicated in neurological diseases. The present work focuses on studying the molecular consequences of DGCR14 overexpression in a human cell model, HeLa cells, at the metabolic level using Gas Chromatography-(ion trap) Mass Spectrometry. However, to succeed in this, issues regarding the quantification capabilities of the multistep omic analysis procedures needed to be resolved. A major concern refers to the fast quenching of any enzymatic processes, so that the acquired measurements indeed reflect the cellular physiology in vivo. To this end, the experimental design should be appropriately adjusted so that any required sample handling actions before quenching have a minimal effect on cellular physiology. Thus, we investigated the effect of four cell collection protocols and two different washing solutions on the intracellular metabolic profile measurements of a HeLa cell culture. The measurements were interpreted in the context of the known cancer cell metabolic physiology and the protocol with the minimum possible effect on cellular physiology was specified. Among the results of this study, valuable information about the metabolic physiology of the immortal cell line arise, which improved our knowledge about cancer metabolism under steady or varying environmental conditions. Subsequently, the optimization of the collection procedure enabled us to establish a representative metabolic profile of HeLa cells against which the overexpression of DGCR14 was evaluated without being obscured by the effect of the sample handling. Regarding the overexpressing cells, the metabolomic analysis detected a trend of physiological change connected to specific metabolic pathways indicating strong metabolic stress. To understand how DGCR14 overexpression generates this particular metabolic phenotype, we used the human spliceosomal complex protein-protein interaction (PPI) network and the integrated human PPI meta-database PICKLE to extract additional information about DGCR14 role based on its location with respect to other nodes and hubs. A possible functional correlation of DGCR14 to autophagic and lysosomal mechanisms was established, that will be further evaluated in the future through the analysis, separately and in combination, of the consequences of DGCR14 over- and under-expression at all molecular levels of cellular function.
184

Paleopathology: signs and lesions in skeletal remains of epidemics and diseases of Biblical times in Syro-Palestine

Greeff, Casparus Johannes 30 November 2005 (has links)
This dissertation deals with the study of ancient diseases mentioned in the historical period of the Scriptures in the region of Syro-Palestine. The definition, history, methodology and etymology of the terms relating to biblical diseases are discussed. Leprosy, syphilis, plague and anaemia amongst other diseases leave skeletal signs and lesions. Paleopathologists may reveal these diseases by studying skeletal remains of the population of Syro-Palestine. Criticisms and recommendations are offered for the practical paleopathologist, anthropologist or archaeologist. More interest should be taken in the study of coprolite in every new discovery of human remains. The scarcity of skeletal remains in the region is well known. The past and present law structure, the Halakah, may partly be to blame. The future of paleopathology worldwide is undisputedly the biochemical science of DNA analysis. With this new science the role for macromorphological examination may diminish. The diseases mentioned in the Bible are finding it increasingly difficult to hide behind the words in the Scriptures. / Old Testament and Ancient Near Eastern Studies / MA (Biblical Archaeology)
185

Fabrication of flexible, biofunctional architectures from silk proteins

Pal, Ramendra K 01 January 2017 (has links)
Advances in the biomedical field require functional materials and processes that can lead to devices that are biocompatible, and biodegradable while maintaining high performance and mechanical conformability. In this context, a current shift in focus is towards natural polymers as not only the structural but also functional components of such devices. This poses material-specific functionalization and fabrication related questions in the design and fabrication of such systems. Silk protein biopolymers from the silkworm show tremendous promise in this regard due to intrinsic properties: mechanical performance, optical transparency, biocompatibility, biodegradability, processability, and the ability to entrap and stabilize biomolecules. The unique ensemble of properties indicates opportunities to employ this material into numerous biomedical applications. However, specific processing, functionalization, and fabrication techniques are required to make a successful transition from the silk cocoon to silk-based devices. This research is focused on these challenges to form silk-based functional material and devices for application in areas of therapeutics, bio-optics, and bioelectronics. To make silk proteins mechanically conformable to biological tissues, the first exploration is directed towards the realization of precisely micro-patterned silk proteins in flexible formats. The optical properties of silk proteins are investigated by showing the angle-dependent iridescent behavior of micropatterned proteins, and developing soft micro-optical devices for light concentration and focusing. The optical characteristics and fabrication process reported in the work can lead to the future application of silk proteins in flexible optics and electronics. The microfabrication process of silk proteins is further extended to form shape-defined silk protein microparticles. Here, the specificity of shape and the ability to form monodisperse shapes can be used as shape encoded efficient cargo and contrast agents. Also, these particles can efficiently entrap and stabilize biomolecules for drug delivery and bioimaging applications. Next, a smart confluence of silk sericin and a synthetic functional polymer PEDOT:PSS is shown. The composite materials obtained have synergistic effects from both polymers. Silk proteins impart biodegradability and patternability, while the intrinsically conductive PEDOT:PSS imparts electrical conductivity and electrochemical activity. Conductive micro architectures on rigid as well as flexible formats are shown via a green, water-based fabrication process. The applications of the composite are successfully demonstrated by realizing biosensing and energy storage devices on rigid or flexible forms. The versatility of the approach will lead to the development of a variety of applications such as in bio-optics, bioelectronics, and in the fundamental study of cellular bio electrogenic environments. Finally, to expand the applicability of reported functional polymers and composites beyond the microscale, a method for silk nano-patterning via electron beam lithography is explored. The technique enables one-step fabrication of user defined structures at the submicron and nano-scales. By virtue of acrylate chemistry, a very low energetic beam and dosage are required to form silk nano-architectures. Also, the process can form both positive and negative features depending on the dosage. The fabrication platform can also form nano scale patterns of the conductive composite. The conductive measurements confirm the formation of conductive nanowires and the ability of silk sericin to entrap PEDOT:PSS particles in nanoscale features.
186

Applications of time-resolved spectroscopy for microenvironment sensing and biomolecular interactions studies / Applications de la spectroscopie ultrarapide à l’étude de sondes locales d’environnement et d’interactions biomoléculaires

Skilitsi, Anastasia Ioanna 30 November 2017 (has links)
La spectroscopie UV-Vis résolue en temps a été appliquée à l'étude de différents systèmes moléculaires dont la photophysique est contrôlée par leur interaction avec l’environnement, mais aussi comme outil pour révéler des interactions moléculaires ou des dynamiques structurelles à des échelles de temps comparativement lentes (sec à min.), en utilisant la microfluidique de gouttes pour déclencher une relaxation structurale par des conditions initiales hors équilibre. J'ai appliqué cette approche selon trois axes allant de 1) l'étude approfondie des propriétés émissives des biosenseurs afin de permettre leur utilisation quantitative dans les études d'interactions biomoléculaires, à 2) le développement d'une approche expérimentale originale pour permettre la résolution la cinétique de relaxation structurelle d'une répartition hors équilibre des structures biomoléculaires, et enfin 3) l'application aux biotechnologies à haut débit de la fluorescence résolue en temps pour des analyses d'interactions biomoléculaires précises et rapides, pertinente à la fois pour les domaines académiques et industriels. / In the context of the present thesis, UV-Vis time-resolved spectroscopy was applied targeting the photophysics investigation of different environmentally sensitive molecular systems, but also as a biosensing approach to reveal molecular interactions or structural dynamics on much slower time scales (sec to min), using droplet microfluidics triggering structural relaxation through out-of-equilibrium initial conditions. I thus investigated on a three-axis-target spanning from 1) the in-depth investigation of the emissive properties of biosensors in order to allow their quantitative use in biomolecular interaction studies, to 2) the development of an original experimental approach to enable resolving the structural relaxation kinetics of an out-of-equilibrium distribution of biomolecular structures, and finally 3) the technological application of time resolved fluorescence for precise, rapid, cost effective, biomolecular interaction assays, appealing both for academic and industrial arenas.
187

DEVELOPMENT OF ARYL ISONITRILES AS ANTIMICROBIAL AGENTS, AND TOTAL SYNTHESIS OF 17-NOR-EXCELSINIDINE

Kwaku Kyei-Baffour (6616715) 15 May 2019 (has links)
<p> </p> <p>Infectious diseases caused by bacteria, fungi, and plasmodium parasites are a huge global health problem which ultimately leads to millions of deaths annually. The emergence of strains that exhibit resistance to nearly every class of antimicrobial agents, and the inability to keep up with these resistance trends has brought to the fore the need for new therapeutic agents (antibacterial, antifungal, and antimalarial) with novel scaffolds and functionalities capable of targeting microbial resistance. A novel class of compounds featuring an aryl isonitrile moiety has been discovered that exhibits potent inhibitory activity against several clinically relevant strains of methicillin-resistant <i>Staphylococcus aureus</i> (MRSA). Synthesis, structure-activity relationship (SAR) studies, and biological investigations have led to lead molecules that exhibit anti-MRSA inhibitory activity as low as 1 – 2 µM. The most potent compounds have also been shown to have low toxicity against mammalian cells and exhibit <i>in vivo</i> efficacy in MRSA skin and thigh infection mouse models.</p> <p>The novel aryl isonitriles have also been evaluated for antifungal activity. This study examines the SAR of aryl isonitrile compounds and showed the isonitriles as compounds that exhibit broad spectrum antifungal activity against species of <i>Candida</i> and <i>Cryptococcus</i>. The most potent derivatives are capable of inhibiting growth of these pathogens at concentrations as low as 0.5 µM. Notably, the most active compounds exhibit excellent safety profile and are non-toxic to mammalian cells up to 256 µM.</p> <p>Beyond the antibacterial and antifungal activities, structure-antimalarial relationship analysis of over 40 novel aryl isonitrile compounds has established the importance of the isonitrile functionality as an important moiety for antimalarial activity. Of the many isonitrile compounds exhibiting potent antimalarial activity, two have emerged as leads with activity comparable to that of Artemisinin. The SAR details presented in this study will prove essential for the development new aryl isonitrile analogues to advance them to the next step in the antimalarial drug discovery process.</p> <p>17-nor-Excelsinidine, a zwitterion monoterpene indole alkaloid isolated from <i>Alstonia scholaris</i> is a subject of synthetic scrutiny. This is primarily due to its intriguing chemical structure which includes a bridged bicyclic ammonium moiety, and its anti-adenovirus and anti-HSV activity. Herein we describe a six-step total synthesis of (±)-17-nor-Excelsinidine from tryptamine. Key to the success of this synthesis is the use of palladium-catalyzed carbonylative heck lactamization methodology which built the 6, 7-membered ring lactam in one step. The resulting pentacyclic product, beyond facilitating the easy access to (±)-17-nor-Excelsinidine, could also serve as a precursor to other related indole alkaloids.</p> <br> <p> </p> <p></p>
188

Rôle du désordre conformationnel dans les protéines du virus des oreillons / Investigating the role of intrinsic conformational disorder in mumps virus proteins

Ivashchenko, Stefaniia 01 July 2019 (has links)
Les oreillons sont une maladie très contagieuse causée par le virus ourlien. La méthode préventive (le vaccin) contre ce virus a été déjà mise au point. Par contre, les épidémies récentes restent incontrôlables. Il est donc très important de comprendre le mécanisme moléculaire de son cycle de vie afin d’élaborer le traitement effectif et spécifique. Ce virus appartient à la famille des Paramyxoviridae. Son génome, l’ARN non segmenté monocaténaire de polarité négative, est protégé par la nucléoprotéine (N) en formant des structures filamenteuses nucléocapsides. N joue un rôle essentiel dans la synthèse du génome viral. En effet, cette protéine avec la polymérase et son cofacteur phosphoprotéine (P) constitue la machinerie de transcription-réplication du virus. La N et la P sont composées des régions pliées et dépliées. Malgré que la morphologie du virus ourlien est conservée parmi les autres membres de la famille, il existe quelques différences. Il a été démontré que la P est un oligomère antiparallel avec les deux extrémités d’un côté qui interagissent avec la partie structurale de N (Ncore). Tandis que la fonction de la région désordonnée (Ntail) est compliquée à identifier pour le moment. En comparant avec les autres paramyxovirus connus, Ntail n’interagit pas avec le domaine C-terminal de la P. Le rôle des régions déstructurées de P n’a pas été défini. Dans ce projet, nous dévoilons les mécanismes des interactions entre diverses régions de N et P et nous expliquons comment les domaines intrinsèquement désordonnés de N et P sont impliqués dans la régulation de la machine complexe de réplication virale. Nous avons utilisé la résonance magnétique nucléaire qui est la méthode la plus puissante afin de déterminer la structure, la dynamique et les partenaires d’interaction dont la fonction des protéines dépliées virales. / Mumps is a highly contagious disease caused by the mumps virus. The prevention treatment (vaccine) against it is already in the routine use. However, recent outbreaks still remain uncontrollable. Therefore, it is important to understand the molecular mechanism of the mumps virus life cycle. This virus belongs to the family of Paramyxoviridae. Its genome, negative strand non-segmented RNA is protected by the nucleoprotein (N) by forming filamentous structures called nucleocapsids. N plays an important role in viral genome synthesis. Together with the polymerase and its cofactor phosphoprotein (P) they constitute the transcription-replication machinery. Both N and P contain folded and unfolded regions. Despite mumps virus common morphology with other paramyxovirus, there are some differences. It has been proposed that P is an antiparallel oligomer with two extremities on the one side being in interaction with the structural part of N (Ncore). The function of the disordered domain (Ntail) remains unclear, as it does not seem to bind to the C-terminal part of P, as is the case for other paramyxoviruses. The role of the disordered domains of P is also not known. In this project we revealed mechanisms of interaction between different regions of N and P and we explain how disordered regions of N and P are implicated in the regulation of the complex machinery of viral replication. We used the nuclear magnetic resonance which is the most powerful method to determine structure, dynamics and potential interaction partners, and therefore, function of disordered viral proteins.
189

DESIGN, SYNTHESIS, AND PRECLINICAL EVALUATION OF LIGAND-TARGETED CONJUGATES FOR CANCER RADIOTHERANOSTICS

Spencer D Lindeman (11205204) 29 July 2021 (has links)
For any drug candidate to be approved by the U.S. Food and Drug Administration, it must meet strict standards for safety and efficacy. While the field of nuclear medicine is over 100 years old, traditional methods such as external beams or systematic administration have rarely met these standards or have limited application. Ligand-targeted therapy and diagnostics, or “theranostics,” has emerged in the past several decades as an exciting field that offers new possibilities to design drugs that are both safe and effective. When applied to nuclear medicine, the field of ligand-targeted radioactive theranostics is younger still, with many critical lessons being discovered and applied currently. This dissertation outlines the necessary principles of radioactive theranostic drug design, then demonstrates the application of several more recent techniques to improve both the efficacy and safety of radioactive theranostics targeting two high priority oncological targets: fibroblast activation protein alpha and folate receptor.
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Production and Harvest of Microalgae in Wastewater Raceways with Resource Recycling

Roberts, Alexander Colin 01 December 2015 (has links) (PDF)
Microalgae can be grown on municipal wastewater media to both treat the wastewater and produce feedstock for algae biofuel production. However the reliability of treatment must be demonstrated, as well as high areal algae productivity on recycled wastewater media and efficient sedimentation harvesting. This processes was studied at pilot scale in the present research. A pilot facility was operated with nine CO2-supplemented raceway ponds, each with a 33-m2 surface area and a 0.3-m depth, continuously from March 6, 2013 through September 24, 2014. The ponds were operated as three sets of triplicates with two sets continuously fed primary-clarified municipal wastewater at either a 2-day or 3-day hydraulic residence time (HRT), and one set fed the clarified effluent of the 3-day pond set. This second pond-in-series was operated with a 3-day HRT. Areal biomass productivity is reported as gross and net, the former based only on biomass in the pond effluents and the latter subtracting the volatile suspended solids in the influent from those in the effluent. An estimate was also made of autotrophic biomass productivity, as differentiated from heterotrophic growth. Over a year, net productivity averaged 83 metric tons per hectare per year (MT/ha-yr) for the 2-day HRT ponds, 52 MT/ha-yr for the 3-day HRT ponds, and 44 MT/ha-yr for the 3-day HRT ponds receiving clarified effluent of the first set of 3-day HRT ponds (i.e., recycled water). The lower net productivity of the pond receiving water recycling was attributed to two factors. First, the relatively high influent suspended solids concentrations were subtracted from the effluent suspended solids concentrations before net productivity was calculated. Second, the recycled water contained less soluble organic matter than the primary-clarified wastewater leading to less heterotrophic biomass production. The accumulation of inhibitory allelochemicals is a possible third cause of lower productivity , but no specific information was collected on allelopathy. Algae were harvested from pond effluent by sedimentation, with harvest efficiency most affected by the extent of natural bioflocculation occurring in the ponds. Some forms of bioflocculation are thought to be mediated by bacteria, which often make-up a substantial fraction of the settled flocs. Pond samples settled in 1-L Imhoff cones averaged/L total suspended solids after 24 hours of settling; but all ponds fell short of meeting an averaged/L total suspended solids after a 2 hour interval which would be ideally achieved for wastewater effluent. No relationship was seen between settling performance and the bacterial content of flocs. Soluble carbonaceous biochemical oxygen demand (scBOD5) removal by the raceway ponds was sufficient to meet wastewater treatment requirements year around. Influent scBOD5 concentrations averaged 83 mg/L, and the effluent averaged 5.1 mg/L and 4.2 mg/L for the 2-day and 3-day HRT pond sets, respectively. The variable with the greatest influence on productivity in all pond sets, and settling performance in the recycled water pond set, was season (i.e., co-correlated variables of solar insolation and pond temperature). Neither productivity nor settling appeared to be related to prominent algae genera or prevalence of grazers. The high net productivity achieved with a growth medium of primary clarifier effluent and the generally high settleability of algal-bacterial flocs indicate a good potential for algae wastewater treatment and biofuel production. However, the settling of algae grown on recycled water needs improvement to achieve the full potential of wastewater-grown algae biofuel production.

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