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Chemical studies on some natural products from Myrothamnus flabellifoliusNako, Ndikho January 2014 (has links)
>Magister Scientiae - MSc / Crude extracts from Myrothamnus flabellifolius were fractionated through variouschromatography techniques in order to achieve satisfactory separations. Two compounds, arbutin and lupeol, were isolated from the butanol and ethyl acetate extracts, respectively. Structural elucidation of the compounds was carried out on the basis of 1H and 13C NMR spectroscopy. It was the first time that lupeol had been isolated from M. flabellifolius.The water extract was found to contain heterogeneous pectic polysaccharides. Three polysaccharide fractions were separated from the water extract, namely; MPS, MPS-I and MPS-II. The predominant fraction was found to be MPS, with a molecular weight distribution of 2 X 105 Da. The polysaccharides were made up the following monosaccharides; arabinose, rhamnose, xylose, mannose, galactose and glucose. Monosaccharide composition was determined through acid hydrolysis at high temperatures, followed by GC analysis. The linkage analysis was carried out by GC-MS, following partial methylation of the polysaccharides. The use of human serum albumin (HSA) following its anchoring on magnetic nanoparticles, in order to isolate targeted saponins from Sutherlandia frutescens led to successful isolation of four saponins, namely; sutherlandiosides A-D. The saponins showed great affinity to bind to the HSA.
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Purification of Phage-Displayed HSA-Specific Peptide for Biosensor ProductionHuber, Alexander Domenico 05 June 2019 (has links)
No description available.
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Biosensor Production By Conjugation Of HSA-Specific Peptide To Functionalized Nanotube FiberKenney, Floyd E. 04 May 2018 (has links)
No description available.
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CHARACTERIZING THE BINDING INTERACTION BETWEEN DICYANOGOLD (I) AND HUMAN SERUM ALBUMINMoore, Alison Blythe January 2002 (has links)
No description available.
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Understanding Amyloid Inhibition: Toward a Residue-Resolution Map of the Interactions between the Alzheimer's Aβ-Peptide and Human Serum AlbuminAlgamal, Moustafa 11 1900 (has links)
Amyloidogenesis refers to a process of protein misfolding and aggregation that leads to the formation of highly stable amyloid fibers. Amyloidogenesis may lead to loss of physiological protein function and/or formation of toxic intermediates, which are linked to mutliple human diseases. Amyloidogenesis is inhibited by plasma proteins, which function as extracellular chaperones by binding to stressed and misfolded proteins, including amyloidogenic peptides, and preventing their aggregation. This thesis focuses on the ability of human serum albumin (HSA), the main protein in human plasma, to inhibit amyloidogenesis, with emphasis on the molecular nature of the interactions between HSA and the amyloid β peptide (Aβ) associated with Alzhemier’s disease. HSA is as a key amyloidogenic regulator, a novel function for this protein that goes beyond the traditional HSA roles as plasma osmotic pressure regulator and as binder and carrier of endogenous and exogenous low molecular weight ligands. As a first step towards understanding the detailed molecular nature of these interactions, this thesis will focus on defining the key binding determinants in the interaction between HSA and Aβ peptides. Primarily, we will try to answer two main questions. First, which HSA residues are critical for the recognition of Aβ peptides and the prevention of Aβ aggregation? Second, which Aβ residues are mostly affected by HSA binding? Starting form our knowledge about the stoichiometry and affinity of the Aβ interactions at the level of HSA domains, Chapter 2 addresses the first question through successful applications of a reductionist approach, based on a combination of mutational comparative analyses and fatty acid (FA) competition. This strategy allowed us to identify a short HSA derived peptide that specifically recognizes Aβ and prevents its aggregation. In Chapter 3, we examine the effect of HSA on the pseudo-equilibrium state between Aβ monomers and protofibrils. Using Dark state Exchange Saturation Transfer (DEST), Saturation Transfer Difference (STD) and 15N T2 relaxation experiments, we show that Aβ peptides interact with HSA via a dual mechanism. First, selected residues in Aβ (1-40) monomers bind specifically but weakly to HSA (Kd = 0.1 - 1 mM). Second, HSA competes with Aβ monomers for the binding to the protofibrils, as indicated by an HSA-dependent decrease in the direct vs. tethered probabilities for contacts between Aβ monomer residues and the protofibril surface. The effect of HSA mimics that of dilution for the majority of the Aβ (1-40) residues involved in the cross-beta strands of amyloid fibrils. Finally, Chapter 4 will outline future investigations to address currently open questions about HSA dynamics, HSA-Aβ and HSA-FA interactions, for which we acquired preliminary data. / Thesis / Master of Science (MSc)
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Microbubble fermentation of recombinant Pichia pastoris for human serum albumin productionZhang, Wei 24 July 2003 (has links)
The high cell density fermentation of recombinant Pichia pastoris for human serum albumin (HSA) production is a high oxygen demand process. The oxygen demand is usually met by increased agitation rate and use of oxygen-enriched air. Microbubble fermentation however can supply adequate oxygen to the microorganisms at relatively low agitation rates because of improved mass transfer of the microbubbles used for the sparging. Conventionally sparged fermentations were conducted for the production of HSA using P. pastoris at agitation rates of 350, 500, and 750 rpm, and were compared to MBD sparged fermentation at 150, 350, and 500 rpm agitation rates. The MBD improved the volumetric oxygen transfer coefficient (kLa) and subsequently increased the cell mass and protein production compared to conventional fermentation.
Cell production in MBD fermentation at 350 rpm was 4.6 times higher than that in conventional fermentation at 350 rpm, but similar to that in the conventional 750 rpm. Maximum cell mass productivity in the conventional 350 rpm was only 0.37 g / (L·h), while the maximum value in MBD 350 rpm was 2.0 g / (L·h), which was similar to 2.2 g / (L·h) in the conventional 750 rpm. Biomass yield on glycerol Ys (g cell/ g glycerol) was 0.334 g / g in the conventional 350 rpm, 0.431 g / g in MBD 350 rpm and 0.438 g / g in the conventional 750 rpm. Protein production in MBD 350 rpm was 7.3 times higher than that in the conventional 350 rpm, but similar to the conventional 750 rpm. Maximum protein productivity in the conventional 350 rpm was 0.37 mg / (L·h), 2.8 mg / (L·h) in MBD 350 rpm, and 3.3 mg / (L·h) in the conventional 750 rpm. Protein yield on methanol Yp (mg protein / g methanol) was 1.57 mg /g in the conventional 350 rpm, 5.02 in MBD 350 rpm, and 5.21 in the conventional 750 rpm.
The volumetric oxygen transfer coefficient kLa was 1011.9 h-1 in MBD 350 rpm, which was 6.1 times higher than that in the conventional 350 rpm (164.9 h-1) but was similar to the conventional 750 rpm (1098 h-1). Therefore, MBD fermentation results at low agitation of 350 rpm were similar to those in the conventional fermentation at high agitation of 750 rpm. There was considerable improvement in oxygen transfer to the microorganism using MBD sparging relative to the conventional sparging.
Conventional fermentations were conducted both in a Biostat Q fermenter (small) at 500 rpm, 750 rpm, and 1000 rpm, and in a Bioflo III fermenter (large) at 350 rpm, 500 rpm, and 750 rpm. At the same agitation rate of 500 rpm, cell production in the large reactor was 3.8 times higher than that in the small one, and no detectable protein was produced in the small reactor at 500 rpm. At the same agitation rate of 750 rpm, both cell production and protein production in the large reactor were 4.6 times higher than the small reactor. Thus, the Bioflo III fermenter showed higher oxygen transfer efficiency than the Biostat Q fermenter, because of the more efficient aeration design of the Bioflo III fermenter. / Master of Science
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Protein interaction with polyelectrolytes and ligands: A structural and thermodynamic investigationYu, Shun 29 August 2017 (has links)
Der erste Teil dieser Arbeit untersucht die Ladungswechselwirkung zwischen Proteinen und Polyelektrolyten. Dabei wird die Bindung von Polyakrylsäure (PAA) als kurzes Modell-Polyelektrolyt an Humanalbumin (HSA) in einer umfassenden experimentellen und theoretischen Studie untersucht und sehr gute Übereinstimmung der Resultate konnte festgestellt werden. Die Computersimulationen in dieser Arbeit wurden von Xiao Xu im Rahmen seiner Promotion durchgeführt. Thermodynamische Daten wurden mit Hilfe von Isothermer Titrationskalorimetrie (ITC) gesammelt und strukturelle Untersuchungen wurden mit Hilfe von Neutronenkleinwinkelstreuung (SANS) durchgeführt. Die Analyse von Bindungsaffinitäten zeigte eine eins zu eins Bindung von PAA mit HSA, die entropisch getrieben ist und strukturellen Untersuchungen weisen eine stabile Proteilstruktur unabhängig von der Adsorption durch PAA auf.
Im zweiten Teil der Arbeit wird die Wechselwirkung zweier uremischer Toxinen, nämlich Phenylessigsäure (PhAA) und Indoxylsulfat (IDS), mit HSA untersucht. Eine wichtige Schlussfolgerung aus der Analyse der ITC Daten ist, dass begünstigende, hydrophobe Wechselwirkungen die treibende Kraft für die Adsorption von Toxinen an HSA sind, und dass hierbei die Enthalpie-Entropie-Kompensation (EEC) zu tragen kommt. Weiterhin zeigen SANS Untersuchungen, dass die Proteinstruktur trotz Adsorption stabil bleibt und konnte außerdem über Interpartikulare Wechselwirkung von HSA-Toxin Komplexen aufklären.
Im Allgemeinen ist HSA strukturell unverändert durch die Adsorption von Liganden. Diese Feststellung erlaubt die Interpretation von ITC Daten, da damit gemessene Wärmeprozesse ausschließlich von Bindungsprozessen herrühren. Die vorliegende Arbeit konnte zeigen, dass eine ausführliche thermodynamische Analyse durch Kombination von theoretischer mit experimenteller Arbeit, eine umfassende Einsicht in die Mechanismen von Bindungsprozessen ermöglicht. / The first part of the thesis explores the charge-charge interaction between proteins and polyelectrolytes. Polyacrylic acid (PAA) is used as a short model polyelectrolyte to interact with human serum albumin (HSA) the most abundand protein in blood, in a comprehensive experimental and theoretical study. The results thereby coincide very well. Computer simulation studies were performed by Xiao Xu within the framework of his PhD thesis. Thermodynamic data were collected by means of isothermal titration calorimetry (ITC) and structural analysis performed using small-angle neutron scattering (SANS). The analysis of binding free energies revealed one to one binding that is mainly driven by entropy. Structural investigations give proof of the stability of the protein beside adsorption.
In the second part, the interaction of two uremic toxins, namely phenylacetic acid (PhAA) and indoxyl sulfate (IDS), with HSA is studied. Systematic ITC experiments reveal two binding sites for both of the two toxins and show small dependence of binding affinities on ionic strength in contrast to PAA adsorption to HSA. This leads to the key conclusion that the favorable hydrophobic interaction is the driving contribution for adsorption and enthalpy-entropy compensation (EEC) effect comes into play. SANS studies of high concentrated HSA-toxin solutions proofed the stability of the protein structure and shed light on the interparticle interaction of HSA-toxin complexes.
In general, HSA is structurally robust regardless of ligand uptake. This finding allows the interpretation of ITC data by confirming that the measured heat signals are purely associated to the binding process. The present thesis has demonstrated that a full thermodynamic analysis in combination with theoretical modelling can provide a comprehensive understanding of binding in terms of identifying driving forces and their contributions to protein ligand interaction.
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Investigação química de complexos de coordenação dos antibióticos enrofloxacina e norfloxacina combinados ao íon Ru(III) e suas interações com biomoléculas alvo / Chemical Investigation of coordination compounds with enrofloxacin and norfloxacin antibiotics combined to Ru (III) ion and their interations with target biomolecule.Reis, Felipe Costa Claro 28 July 2014 (has links)
Este trabalho tem como objetivo sintetizar e caracterizar um novo complexo mononuclear de rutênio (III) e enrofloxacina (enro, fármaco antibacteriano da família das fluoroquinolonas), [Ru(enro)3].nH2O. Foram testadas várias rotas sintéticas e apenas a partir de uma delas obteve-se o composto desejado. O produto foi caracterizado pelas técnicas espectroscópicas de absorção na região do UV-visível e do infra-vermelho. Através desta última técnica foi possível determinar o modo pelo qual a enrofloxacina se coordena ao íon rutênio: a coordenação ocorre de modo bidentado através do oxigênio da piridona e do oxigênio do grupamento carboxilato. Outro objetivo deste trabalho foi investigar a interação do complexo mononuclear de rutênio (III) e norfloxacina, [Ru(nor)3].nH2O, com a albumina de soro humano (HSA), através da técnica de luminescência. Mais especificamente pelo estudo da supressão da luminescência dos resíduos de triptofano, aplicando-se o modelo de tratamento da supressão bimolecular de Stern-Volmer. O estudo de supressão de fluorescência mostrou, por meio de espectros de emissão da HSA, que com o aumento da concentração do complexo [Ru(nor)3].nH2O na solução de HSA, ocorre uma redução gradual da luminescência da HSA, devido a alterações da conformação da proteína, que sugerem alteração do microambiente próximos aos resíduos de triptofano. A partir do tratamento dos dados pode-se determinar tanto K_sv quanto a constante cinética do processo de supressão, que mostraram uma dependência com a temperatura sugerindo como mecanismo predominante de supressão o mecanismo dinâmico. Porém essa conclusão foi revista a partir da determinação dos tempos de vida do estado excitado da HSA, e pode-se concluir que o mecanismo predominante à temperatura ambiente é o mecanismo estático, porém com o aumento da temperatura ocorre a predominância do mecanismo do tipo dinâmico. Através da determinação dos parâmetros termodinâmicos, concluiu-se que as interações entre a HSA e o complexo são espontâneas, e forças de van der Waals e ligações de hidrogênio estão envolvidas na ligação entre a HSA e o supressor. / This work aims to synthesize and characterize a new mononuclear ruthenium (III) complex and enrofloxacin (enro, antibacterial drug of the fluoroquinolone family), [Ru(enro)3].nH2O. Several synthetic routes were tested, but only from one of them it was obtained the desired compound. The product was characterized by spectroscopic techniques of absorption in UV-visible and infra-red regions. Through this last technique, it was possible to determine the coordination mode of enrofloxacin to the ruthenium ion: the coordination occurs in a bidentate way through the pyridone oxygen and the oxygen of the carboxylate group. Another aim of this study was to investigate the interaction of mononuclear ruthenium (III) complex and the norfloxacin, [Ru(nor)3].nH2O, with the human serum albumin (HSA), through the technique of luminescence. More specifically, by the study of the quenching of luminescence of tryptophan residues, by applying the Stern-Volmers model of treatment of bimolecular suppression. The fluorescence quenching study showed, through the emission spectra of HSA, that increasing the complex concentration in HSA solution, there is a gradual reduction of the luminescence of HSA, due to the conformational changes of the protein that suggests the change of microenvironment near tryptophan residues. From the data processing it is possible to determine both K_sv and the kinetic constant of the suppression process, which showed temperature dependence, suggesting as the predominant mechanism of quenching the dynamic mechanism. However, this conclusion has been revised from the determination of the lifetimes of the excited state of HSA, and it can be concluded that the predominant mechanism at room temperature is the static mechanism, but with the temperatures increase, it occurs the predominance of the dynamic type mechanism. By determining the thermodynamic parameters, it was concluded that the interactions between HSA and the complex are spontaneous, and Van der Waals forces and hydrogen bonds are involved in the binding between HSA and suppressor.
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Behavioral Effects of Functionalized CdSe/ZnS Quantum Dots in Self-Organization and Protein FibrillationVannoy, Charles Harvey 11 June 2010 (has links)
Advances in recent nanoscience technologies have generated a new compilation of biocompatible, fluorescent nanoparticles derived from semiconductor quantum dots (QDs). QDs are extremely small in size and possess very large surface areas, which gives them unique physical properties and applications distinct from those of bulk systems. When exposed to biological fluid, these QDs may become coated with proteins and other biomolecules given their dynamic nature. These protein-QD systems may affect or enhance the changes in protein structure and stability, leading to the destruction of biological function. It is believed that these QDs can act as nucleation centers and subsequently promote protein fibril formation. Protein fibrillation is closely associated with many fatal human diseases, including neurodegenerative diseases and a variety of systemic amyloidoses. This topic of protein-QD interaction brings about many key issues and concerns, especially with respect to the potential risks to human health and the environment. Herein, the behavioral effects of dihydrolipoic acid (DHLA)-capped CdSe/ZnS (core/shell) QDs in hen egg-white lysozyme (HEWL) and human serum albumin (HSA) protein systems were systematically analyzed. This study gives rise to a better understanding of the potentially useful application of these protein-QD systems in nanobiotechnology and nanomedicine as a bioimaging tool and/or as a reference for controlled biological self-assembly processes.
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Observation Of Spectral Changes To Trp-214 Residue In Human Serum Albumin Upon Binding With Mangiferin And Near Infrared DyesNovak, Jennifer 11 August 2015 (has links)
A novel approach of using near infrared region (NIR) dyes is applied to elucidate the binding interaction between human serum albumin (HSA) and mangiferin (MGF). HSA is a blood carrier protein used for drug delivery, while mangiferin is a natural polyphenol found in mangoes that possesses numerous beneficial health properties. The NIR dyes are used as a probe to investigate MGF binding interaction with HSA via monitoring fluorescence of Trp-214 residue. Molecular modeling is used for docking and semi-empirical analysis. The investigation of the binding interaction between Trp-214 and MGF is significant, for it may offer broader pharmacological insight and applications for the polyphenol. Mangiferin in proposed to bind with a 2:1 stoichiometric ratio with HSA to the Trp-214 residue in subdomain IIA and another possible binding site to be determined in future studies. Spectral changes suggest a stabilized protein conformation upon mangiferin binding with the addition of NIR dye E-06 and MHI-06.
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