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Erzeugung funktionaler Schichten auf Basis von bakteriellen HüllproteinenWeinert, Ulrike 05 July 2013 (has links)
Die hier vorliegende Arbeit beschäftigt sich mit Eignung bakterieller Hüllproteine als Bindungsmatrix für die Kopplung funktionaler Moleküle mit dem Ziel, sensorische Schichten zu erzeugen. Bakterielle Hüllproteine sind biologische SAMs, anderen Oberfläche sich modifizierbare COOH-, NH2- und OH-Gruppen befinden. Die Ausbildung polymerer Strukturen erfolgt dabei in wässrigen Systemen und auf Oberflächen. Im Zuge der boomenden Entwicklung von Biosensoren werden insbesondere Biotemplate gesucht, die zwischen biologischer Komponente und Sensoroberfläche vermitteln. Bakterielle Hüllproteine stellen eine solche Zwischenschicht dar. Als Anwendungsbeispiel wurden die Proteine daher mit einem FRET-Paar und Thrombin und Kanamycin-Aptameren modifiziert. Hierbei wurden das FRET-Paar H488 und H555 an die bakteriellen Hüllproteine der beiden Haldenisolate A12 und B53 mittels EDC mit einer Modifizierungsrate von 0,54 molFarbstoff/molProtein kovalent gebunden. Bei der vorhandenen p4-Symmetrie bedeutet dies, dass ein FRET-Paar pro Einheitszelle vorhanden war. Der Nachweis eines Energietransfers zwischen den beiden am Protein gebundenen Fluoreszenzfarbstoffen H488 und H555 erfolgte mittels statischer und zeitaufgelöster Fluoreszenzmessung.
Die Ergebnisse zeigten, dass ein Energietransfer nur möglich war, wenn die Proteine in polymerer Form vorlagen, unabhängig davon, ob sich die Proteine immobilisiert an einer Oberfläche oder in wässriger Lösung befanden. Mittels Variieren des Donor-Akzeptor-Verhältnisses konnte ein maximaler Energietransfer von 40 % generiert werden, wenn das Verhältnis der Fluoreszenzfarbstoffe von Donor und Akzeptor 4 betrug. Die Fluoreszenzintensität der Fluorophore wurde durch die Bindung an die Proteine nicht verringert oder gelöscht. Dies legt nahe, dass die Farbstoffe in den hydrophoben Poren immobilisiert wurden und die Poren die Fluoreszenzfarbstoffe schützen. Um weitere Aussagen über die Lage der gebundenen Fluoreszenzfarbstoffe zu erhalten, wurden die bakteriellen Hüllproteine der Stämme A12 und B53 enzymatisch verdaut und die Fragmente mittels SEC und SDS-PAGE untersucht. Dabei zeigten sich je nach Enzym und Protein unterschiedliche Bandenmuster bezüglich modifizierter und nativer Hüllproteine. Dies belegt, dass die Fluoreszenzfarbstoffe an NH2-und COOH-Gruppen der Proteine gebunden wurden und so teilweise den enzymatischen Verdau hinderten. Die SEC deutet an, dass die Fluoreszenzfarbstoffe an verschiedenen Stellen am Protein gebunden wurden.
In einem zweiten Beispiel wurde das bakterielle Hüllprotein von A12 mit einem Aptamer modifiziert. Aptamere sind kurze einzelsträngige Oligonukleotide, die u.a. mittels ihrer ausgebildeten 3D-Struktur spezifisch Zielstrukturen reversibel binden können. Die hier verwendeten Aptamere binden spezifisch Thrombin und Kanamycin. Die Aptamere wurden mit Hilfe einer der beiden Vernetzer PMPI oder Sulfo-SMCC an die bakteriellen Hüllproteine kovalent gebunden. Nach dem Modifizieren der Proteine wurden diese auf entsprechenden Sensorchips immobilisiert und die Aktivität des gekoppelten Aptamers mittels Affinitätsmessungen, SPR-Spektroskopie und QCM-D-Messungen analysiert. Die Funktion des gebundenen Thrombinaptamers konnte mittels Affinitätsmessungen und QCM-D nachgewiesen werden und entspricht in beiden Fällen einer Bindung von 2 nmol Thrombin pro Quadratzentimeter. Die Funktionalität des Kanamycinaptamers sollte mittels SPR bestimmt werden, jedoch konnte keine Funktionalität des gekoppelten Kanamycinaptamers nachgewiesen werden. Alle Messungen bestätigten jedoch, dass die Bindungsmatrix aus bakteriellen Hüllproteinen keinerlei oder nur ein sehr geringes Hintergrundsignal liefert.
Werden nun beide Komponenten, FRET-Paar und Aptamere, an das Protein gebunden, ist es möglich, eine sensorische Schicht zu erzeugen. Die Zielstruktur, welche detektiert werden soll, wird an das Aptamer gebunden und so in räumliche Nähe zur Sensorfläche gebracht. Stell die Zielstruktur einen Fluoreszenzlöscher dar, so wird der Energietransfer durch die räumliche Nähe des Fluoreszenzlöscher gestört. Die Detektion des Zielmoleküls erfolgt nun über die Änderung von Fluoreszenzintensitäten. Die hier vorgelegte Arbeit soll einen Grundstein legen für die Entwicklung eines solchen Sensors und insbesondere die Detektion eines Energietransfers optimieren und Schwachstellen in der Detektion nachweisen. Die systematische Untersuchung der Fluoreszenzfarbstoffe auf dem Protein ermöglichen es, in zukünftigen Arbeiten einen FRET zweifelsfrei zu detektieren. Die Modifizierung von bakteriellen Hüllproteinen von A12 mit Aptameren und die Detektion der Funktionalität der Aptamere mittels verschiedener Methoden zeigte auf, dass die bakteriellen Hüllproteine als universelle Bindungsmatrix für sensorische Moleküle dienen können, bei denen Affinitätsmessungen, SPR- oder QCM-D-Messungen genutzt werden. Besonders hervorzuheben ist, dass bakterielle Hüllproteine nahezu kein Hintergrundsignal liefern und aufgrund ihrer dünnen Monolage von etwa 6 - 9 nm die Sensitivität der Messungen nur gering beeinträchtigen.
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Lactobacillus helveticus: meccanismi di adattamento al tratto gastro-intestinale. / LACTOBACILLUS HELVETICUS: GUT ADAPTATION MECHAMISMSMOLINARI, PAOLA 03 April 2019 (has links)
I lattobacilli probiotici devono sopravvivere al passaggio attraverso il tratto intestinale, che significa principalmente al pH acido nello stomaco e alla concentrazione di bile nell'intestino tenue. Questi tratti richiedono un adattamento specifico, suggerendo che gli isolati intestinali hanno più probabilità di sopravvivere dopo l'ingestione. L. helveticus CNBL 1254, un ceppo isolato dall'ambiente lattiero-caseario, mostra - in vitro - una gamma completa di fenotipi correlati all'adattamento intestinale: è, infatti, in grado di sopravvivere al transito gastrointestinale chimicamente simulato e ai sali biliari, anche se il suo gene bsh ha una delezione che lo rende non funzionale. L'analisi di RNA-Seq condotta in presenza dello 0,1% di sali biliari evidenzia una sovraespressione della proteina precursore del S-layer e del aggregation promoting factor. Inoltre, nelle proteine selezionate dall'analisi VIP della statistica multivariata OPLS-DA condotta per i dati proteomici, abbiamo riscontrato un aumento globale delle proteine ribosomiali e del S-layer con un VIP-score di 1,33 e un fold change di 2,41 che suggerisce la presenza, in questo ceppo di L. helveticus, di un meccanismo di resistenza non ancora descritto per l'ambiente intestinale. / Probiotic lactobacilli have to survive to the passage through the intestinal tract, mainly acid pH in the stomach and bile concentration in the small intestine. These traits require a specific niche adaptation, suggesting that intestinal isolates are most likely to survive after ingestion. However L. helveticus CNBL 1254, a strain isolated from dairy environment, shows in vitro a full range of phenotypes related to gut adaptation. It is able to survival to the chemically simulated gastrointestinal transit and to bile salts, even if its bsh gene has a deletion that make it non-functional. RNA-Seq analysis conducted in the presence of 0.1% of bile salts highlights an over expression of S-layer protein precursor and aggregation promoting factor. Furthermore in the proteins selected by VIP analysis of OPLS-DA multivariate statistic conducted for proteomic data ,we have found global increase in the ribosomal proteins and a S-layer protein with a VIP-score of 1.33 and a fold change of 2.41 suggesting the presence in this strain of L. helveticus of a not yet described mechanism of resistance to the gut environment.
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Caracterização fisiológica e genética do Lactobacillus delbrueckii UFV H2b20 desprovido da capacidade de imunoestimulação / Genetic and physiologic characterization of a Lactobacillus delbrueckii UFV H2b20 mutant unable of immunestimulationTeixeira, Leonardo Maestri 14 May 2004 (has links)
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Previous issue date: 2004-05-14 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Foi feita a caracterização de um mutante espontâneo do Lactobacillus delbrueckii UFV H2b20 que mostrou-se desprovido da capacidade de imunoestimulação e também a investigação do possível papel da seqüência de inserção ISLdH2b20 nessa mutação. A confirmação da identidade genética de L. delbrueckii UFV H2b20 com a do mutante desprovido da capacidade de imunoestimular o hospedeiro foi realizada por análise dos perfis de PCR-DGGE. Ambas bactérias apresentaram na microscopia eletrônica de transmissão característica peculiar do H2b20, a de formar bastonete alongado quando na fase estacionária. As células do mutante mostraram-se com diâmetro maior do que as da cultura do L. delbrueckii UFV H2b20, porém as velocidades especificas máximas de crescimento (μ max ) foram iguais. As células do mutante sofrem lise mais rápida do que as da cultura original selvagem quando em presença de baixas concentrações de mutanolisina, no entanto, o perfil de lise é idêntico em presença de lisozima. A hidrofobicidade de superfície das células, determinada pelo teste de MATH, é maior nas células da cultura original do L. delbrueckii UFV H2b20. Os perfis de proteínas de superfície não se distinguem quanto ao número e posição das bandas em SDS-PAGE, contudo a banda referente à proteína de aproximadamente 36kDa apresentou mais proteína nos extratos do tipo selvagem do que a do mutante. O mutante apresentou uma maior quantidade de proteínas em quase todas as outras bandas, com destaque para duas bandas, 60 kDa e 75 kDa. O estudo de distribuição da ISLdH2b20 nos isolados selvagem e mutante, feito por análise de Southern, mostrou mesmo perfil de distribuição dessa seqüência de inserção nos dois solados. Os resultados indicam a possível participação de uma proteína de 36 kDa no processo de imunoestimulação do H2b20, possivelmente da camada S, e que a instabilidade desse, quanto à capacidade de imunoestimulação, não tem a participação direta da seqüência de inserção ISLdH2b20 em particular. / A mutant of L. delbrueckii UFV H2b20, without the capacity of immunestimulation, was characterized and the possible role of the insertional sequence ISLdH2b20 in this mutation also. PCR-DGGE confirmed its genetic identity as L. delbrueckii UFV H2b20. Transmission electron microscopy demonstrated the characteristic morphology of the cells in the stationary phase, when they appeared as long rods with 0,653μm diameter, for the wild type, and 0,735μm, for the mutant. Maximum specific growth rate (μ max ) was similar for both cultures. The effect of lysozyme on cells of H2b20 and mutants was the same; however, mutanolysin had a more rapid lytic effect on mutant cells, when in lower concentrations. The superficial hydrophobicity of the cells, determined by microbial adhesion to hexadecane (MATH) is higher in wild type cells. The profiles protein of superficial proteins, by SDS-PAGE, are similar when the position and number of bands are considered, however, the band represented by one protein with approximately 36kDa showed more protein in the wild type extract than in the mutant extract. The mutant presented more proteins in almost all of the other bands, especially in the two bands representing proteins with 60kDa and 75kDa. The consolidated results point to a possible role for the 36kDa protein in the immunestimulation capacity of the wild type cells. This is possible the S-layer protein of L. delbrueckii UFV H2b20. Southern analysis of the wild type and the mutant’s DNAs indicated no difference in the distribution of the several copies of ISLdH2b20 between the two strains. This leads to the conclusion that the mutation, which introduced to loss of the immunestimulation capacity, is not the result transposition of this putative element.
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Directed Interface Modifications by Genetically Engineered Surface Active ProteinsGruner, Leopold Joachim 18 December 2017 (has links) (PDF)
This work was performed in the framework of an interdisciplinary graduate program that focuses on the establishment and extension of innovative compounds for the packaging of electronic systems. Such chemically or biotechnologically tailored compounds can be used for the direct patterning of optically, magnetically or biologically functional structures in nano- and biotechnical products. In order to organize matter at the nanometer scale, imprinting litho-graphy techniques or self-organization processes are appropriate. Fine-tuning of numerous engineering processes requires continuous and high precision monitoring as well as control of diverse parameters. These demands are only partially met by physical or chemical components since they use surrogate parameters, measure off-line, or provide insufficient performances. Biological compounds, in particular protein-based feedback systems, fulfill certain system requirements to a considerable degree.
Hydrophobins and S-layer proteins are surface active proteins, produced by filamentous fungi or bacteria. In nature, these (self )assembly proteins form highly ordered and robust structures. In addition, their tolerance for different sequence manipulations and chemical modifications allows extensive functionalization of these nanometer-sized proteins. Hence, these surface active proteins can also be fused with other protein domains to create chimera, which retain function of both original proteins. In conclusion, both hydrophobins and S-layer proteins represent a versatile tool in numerous fields of applied biotechnology, medicine or diagnostics. But until now, efficient in vitro operation in molecular designed protein coatings is strongly restricted due to their complex assembly mechanism.
In the first phase of this work, it was demonstrated, that representatives of class I and class II hydrophobins tend to form multilayered structures on solid surfaces. It was found that only two protein orientations seems to be preferentially formed. In the process of assembly, the orientation of the first hydrophobin layer strictly depends on the substrate wettability. Consequently, each of the following hydrophobin layers is inverse oriented to the layer before. This alternating assembly mechanism has to be taken into account, when working with functionalized hydrophobins, because a hydrophobin-fused functional protein domain is exclusively located on one side of the protein. Due to the densely packed structure of surface active proteins, a fused functional domain, embedded between two hydrophobins is barely available for external reagents. Basically, the simultaneous existence of a broad spectrum of ordered and disordered assembly structures, demonstrated the need of an uniform protein film assembly for applications in fine-diagnostics or biomedicine.
With regard to molecular designed protein coatings, this work further aimed at establishing conditions to develop a method for a ‘layer-by-layer’ assembly of protein chimeras. Based on their amphiphilic character, self-assembly behavior of surface active proteins can be influenced by conventional ionic surfactants. In order to study the effect of surfactants on the composition and morphology of adsorbed protein films, contact angle measurements, nulling ellipsometry, SEM, AFM and AFAM were performed. It was found that the layer thickness of assembled protein films is strictly dependent on the amount of added surfactant. At certain threshold surfactant concentrations, hydrophobins and S-layer proteins assemble in uniform layers, which are as thick as expected for a protein monolayer or a bilayer. Assembled protein films are covered by a smooth surfactant layer, which prevents further protein assembly. AFAM measurements reveal the formation of well defined lattice structures under the coverage of surfactants. Even the removal of the surfactant layer is possible without inter-fering with protein specific secondary structures. Solvent accessibility and functionality of protein-fused domains was successfully demonstrated. As compared to conventional assembly techniques, this novel protein deposition method offers a possibility for a ‘directed’ protein coating on solid surfaces. In addition, it guarantees broadly ranged homogeneous assembly of protein chimeras on non-planar or even porous surfaces independent of their position.
Finally, a prototype for an interfacial FRET was developed in a close collaboration with the Institute of Physical Chemistry (TUD). This innovative FRET between semiconducting nano-particles and illuminating protein chimeras takes place across an oil/water interface. Hydro-phobins were used to stabilize artificial oil droplets in aqueous solution. These small proteins possess the ability to attach fused functional domains very close to an oil/water interface. When, in addition to this, an optically active nanostructure directly docks to the hydrophobin, the distance of a protein-fused domain and the nanostructure are in the range of the FÖRSTER radius. It was successfully demonstrated that quantum dots and fluorescent proteins fulfill the spectroscopic requirements of such a donor/acceptor pair. The FRET performance of these excitable oil droplets was examined as a ‘proof of concept’. Due to its modular design, this signal amplification setup could be exploited in numerous fields of technical application ranging from quantification of micronutrient to photothermal cancer therapy.
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Directed Interface Modifications by Genetically Engineered Surface Active ProteinsGruner, Leopold Joachim 05 November 2012 (has links)
This work was performed in the framework of an interdisciplinary graduate program that focuses on the establishment and extension of innovative compounds for the packaging of electronic systems. Such chemically or biotechnologically tailored compounds can be used for the direct patterning of optically, magnetically or biologically functional structures in nano- and biotechnical products. In order to organize matter at the nanometer scale, imprinting litho-graphy techniques or self-organization processes are appropriate. Fine-tuning of numerous engineering processes requires continuous and high precision monitoring as well as control of diverse parameters. These demands are only partially met by physical or chemical components since they use surrogate parameters, measure off-line, or provide insufficient performances. Biological compounds, in particular protein-based feedback systems, fulfill certain system requirements to a considerable degree.
Hydrophobins and S-layer proteins are surface active proteins, produced by filamentous fungi or bacteria. In nature, these (self )assembly proteins form highly ordered and robust structures. In addition, their tolerance for different sequence manipulations and chemical modifications allows extensive functionalization of these nanometer-sized proteins. Hence, these surface active proteins can also be fused with other protein domains to create chimera, which retain function of both original proteins. In conclusion, both hydrophobins and S-layer proteins represent a versatile tool in numerous fields of applied biotechnology, medicine or diagnostics. But until now, efficient in vitro operation in molecular designed protein coatings is strongly restricted due to their complex assembly mechanism.
In the first phase of this work, it was demonstrated, that representatives of class I and class II hydrophobins tend to form multilayered structures on solid surfaces. It was found that only two protein orientations seems to be preferentially formed. In the process of assembly, the orientation of the first hydrophobin layer strictly depends on the substrate wettability. Consequently, each of the following hydrophobin layers is inverse oriented to the layer before. This alternating assembly mechanism has to be taken into account, when working with functionalized hydrophobins, because a hydrophobin-fused functional protein domain is exclusively located on one side of the protein. Due to the densely packed structure of surface active proteins, a fused functional domain, embedded between two hydrophobins is barely available for external reagents. Basically, the simultaneous existence of a broad spectrum of ordered and disordered assembly structures, demonstrated the need of an uniform protein film assembly for applications in fine-diagnostics or biomedicine.
With regard to molecular designed protein coatings, this work further aimed at establishing conditions to develop a method for a ‘layer-by-layer’ assembly of protein chimeras. Based on their amphiphilic character, self-assembly behavior of surface active proteins can be influenced by conventional ionic surfactants. In order to study the effect of surfactants on the composition and morphology of adsorbed protein films, contact angle measurements, nulling ellipsometry, SEM, AFM and AFAM were performed. It was found that the layer thickness of assembled protein films is strictly dependent on the amount of added surfactant. At certain threshold surfactant concentrations, hydrophobins and S-layer proteins assemble in uniform layers, which are as thick as expected for a protein monolayer or a bilayer. Assembled protein films are covered by a smooth surfactant layer, which prevents further protein assembly. AFAM measurements reveal the formation of well defined lattice structures under the coverage of surfactants. Even the removal of the surfactant layer is possible without inter-fering with protein specific secondary structures. Solvent accessibility and functionality of protein-fused domains was successfully demonstrated. As compared to conventional assembly techniques, this novel protein deposition method offers a possibility for a ‘directed’ protein coating on solid surfaces. In addition, it guarantees broadly ranged homogeneous assembly of protein chimeras on non-planar or even porous surfaces independent of their position.
Finally, a prototype for an interfacial FRET was developed in a close collaboration with the Institute of Physical Chemistry (TUD). This innovative FRET between semiconducting nano-particles and illuminating protein chimeras takes place across an oil/water interface. Hydro-phobins were used to stabilize artificial oil droplets in aqueous solution. These small proteins possess the ability to attach fused functional domains very close to an oil/water interface. When, in addition to this, an optically active nanostructure directly docks to the hydrophobin, the distance of a protein-fused domain and the nanostructure are in the range of the FÖRSTER radius. It was successfully demonstrated that quantum dots and fluorescent proteins fulfill the spectroscopic requirements of such a donor/acceptor pair. The FRET performance of these excitable oil droplets was examined as a ‘proof of concept’. Due to its modular design, this signal amplification setup could be exploited in numerous fields of technical application ranging from quantification of micronutrient to photothermal cancer therapy.
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Genetic engineering of S-layer of <i>Caulobacter crescentus</i> for bioremediation of heavy metalsPatel, Jigar J. 16 December 2009 (has links)
No description available.
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La vectorisation de Propionibacterium freudenreichii CIRM-BIA 129 et de ses protéines immunomodulatrices par la matrice fromagère vers le tube digestif / “The delivery of Propionibacterium freudenreichii CIRM-BIA 129 and of its immunomodulatory proteins by the cheese matrix to the digestive tract”Rabah, Houem 05 March 2019 (has links)
Propionibacterium freudenreichii CIRM-BIA 129 (Pf) est une bactérie bénéfique utilisée comme levain fromager. Elle présente en outre de nombreuses potentialités probiotiques souche-dépendantes, dont la modulation de l’inflammation. Cette propriété résulte de la production de divers métabolites. Les protéines de surface S-layer (Slps), dont la protéine majoritaire SlpB, y jouent également un rôle immunomodulateur. Les propriétés « 2-en-1 », c’est-à-dire à la fois fermentaires et probiotiques, font de Pf un bon candidat pour développer des fromages fonctionnels, afin de prévenir les maladies inflammatoires intestinales. L’objectif de cette thèse était d’étudier l’impact de la matrice fromagère sur les propriétés immunomodulatrices de Pf, via ses protéines Slps, par comparaison à une culture sur ultrafiltrat de lait (UF). Les études conduites in vitro suggèrent que les bactéries provenant du fromage auraient une meilleure capacité de tolérance aux stress gastriques et duodénaux, mais elleauraient une moindre capacité de survie dans le côlon, par comparaison à des bactéries provenant d’une culture sur UF. De plus, la protéolyse digestive des protéines de surface améliore la survie de Pf dans le côlon. Parallèlement, l’étude de digestion in vitro a montré que la protéolyse des protéines de surface a seulement été réduite par la matrice fromagère. Cette protéolyse conduit à l’abolition des effets anti-inflammatoires des protéines Slps, qui ne sont pas exprimées de novo dans l’environnement colique. Ces résultats obtenus in vitro étaient cohérents avec l’étude in vivo qui a mont / Propionibacterium freudenreichii CIRM-BIA 129 (Pf) is a beneficial bacterium used as a cheese starter. It moreover displays versatile strain-dependent probiotic properties, including the modulation of inflammation. This property results from the production of various metabolites. S-layer surface proteins (Slps), including the major SlpB protein, also play an immunomodulatory role. The "2-in-1" properties, i.e. both fermentative and probiotic properties, make Pf a suitable candidate to develop functional cheeses, in order to prevent inflammatory bowel diseases. The aim of this thesis was to study the impact of the cheese matrix on the immunomodulatory properties of Pf, mediated by its Slps proteins, compared to a culture on milk ultrafiltrate (MUF). In vitro studies suggest that the bacteria from the cheese would have a better ability to tolerate gastric and duodenal stresses, but would have less ability to survive in the colon, compared to bacteria from a MUF culture. In addition, thethe digestive proteolysis of surface proteins improves survival of Pf in the colon. In parallel, the in vitro digestion study showed that proteolysis of surface proteins was only limited by the cheese matrix. This proteolysis leads to the abolition of the anti-inflammatory effects of Slps proteins, which are not de novo expressed in the colonic environment. These results, obtained in vitro, were consistent with the in vivo study, which showed that MUF culture and cheese delivered similar amounts of metabolically active bacteria to the piglets’ colon. This in vivo study showed, however, that t
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Bioengineering of S-layers: molecular characterization of the novel S-layer gene sslA of Sporosarcina ureae ATCC 13881 and nanotechnology application of SslA protein derivatives / Bioengineering von S-layern: Molekulare Charakterisierung eines neuen S-layer Gens sslA aus Sporosarcina ureae ATCC 13881 sowie nanotechnologische Anwendung von SslA-Protein DerivatenRyzhkov, Pavel 27 February 2008 (has links) (PDF)
S-layer proteins of S. ureae ATCC 13881 form on the cell surface an S-layer lattice with p4 square type symmetry and a period of about 13.5 nm. These lattices were shown to be the excellent nanotemplates for deposition of regular metal clusters. The synthesis of the S. ureae S-layer protein is highly efficient, the protein accounts for approximately 10-15 % of the total cell protein content, judged by the SDS-PAGE results. Besides, the S-layer protein production is tightly regulated, since only negligible amounts of S-layer proteins are observed in the medium at different cell growth phases. At the same time, mechanisms of the regulation of S-layer protein synthesis are poorly understood. As several hundreds of S-layer proteins are produced per second during the cell growth, the S-layer gene promoters are among the strongest prokaryotic promoters at all. However, little is known about factors regulating the expression of S-layer genes, furthermore, no experimental identification of other upstream regulatory sequences except for -35/-10 and RBS sequences was presented to our knowledge to date. A sequence of the S-layer gene of S. ureae ATCC 13881, encoding the previously described S-layer protein, was identified in this work by combination of different approaches. The largest part of the gene, excluding its upstream regulatory and ORF 5’ regions, was isolated from a genomic library by hybridization. The sequence of the isolated fragment proved to contain additionally an 1.9 kb non-coding region and an incomplete 0.8 kb ORF region in its 3’-part. No RBS sequence and apparent promoter regions could be identified in front of the latter sequence, suggesting that it might represent a pseudogene sequence. The sequences of the 5’ and upstream regions of the S. ureae ATCC 13881 S-layer gene were identified by combination of PCR-sequencing and chromosome walking. Totally, a sequence of the 6.4 kb long region of S. ureae genomic DNA was established. The sequence of the S. ureae S-layer protein was deduced from the respective gene sequence and agreed with the peptide sequences, obtained after N-terminal sequencing of tryptic peptides of the S. ureae ATCC 13881 S-layer protein. For the protein the name SslA was proposed, which is an abbreviation for “Sporosarcina ureae S-layer protein A”. Several specific features were observed in gene organisation of sslA, which are also characteristic for other S-layer genes. The distance between the -35/-10 region and the ATG initiation codon is unusually long and a 41 bp palindromic sequence is present in the immediate vicinity of the -35/-10 region. Besides, a distant location of the rho-independent transcription terminator, which is 647 bp remote from the stop codon, will result in the mRNA transcripts with unusually long trailer region. Both the long 5’ UTR and the long 3’ trailer may have a regulatory function, either by conferring increased mRNA stability and/or by affecting translation efficiency. Potentially these sequences may define the binding sites of regulatory proteins. For example, palindromic sequences constitute the regulatory sites in several bacterial operons and may act as the binding sites of regulatory dimeric proteins. In respect to the conservation of the sslA sequence high similarity to the sequences of other functional S-layer genes, especially the slfA and slfB genes of B. sphaericus, was observed, whereas the results of phylogenetic analysis support the hypothesis that S-layer genes may have evolved via the lateral gene transfer. Based on the sslA sequence, several recombinant proteins with truncations of the terminal protein parts or C-terminal fusion of either EGFP or histidine tags were constructed. For all the truncated or EGFP-fusion SslA derivatives high level overexpression in E. coli was possible. For native SslA a moderate level of expression was observed suggesting that its high intracellular concentration may downregulate the protein synthesis. Interestingly, fluorescence microscopy indicates the same intracellular localization for heterologously produced recombinant proteins with fusions of EGFP either to the precursor or to the native SslA protein, suggesting that SslA secretion signal is not functional in E. coli. Heterologously produced SslA derivatives with truncations of N-, C- or both N- and C-terminal parts were shown to self- assemble in vitro, although the size of self-assembly structures was different from that observed upon the self-assembly of the native SslA. In the latter case extended self-assembly layers with the size up to 5x10 µm were observed, with a surface area of up to two orders of magnitude higher than that of S-layer patches, routinely isolated from S. ureae surface. Dependent on the applied recrystallization conditions preferential formation of single- or multilayer self-assembly structures was observed.
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Reguläre bakterielle Zellhüllenproteine als biomolekulares TemplatWahl, Reiner 17 May 2003 (has links) (PDF)
Bacterial cell wall proteins (S-layer) are - due to both the capability to self-assemble into two-dimensional crystals and their distinct chemical and structural properties - suitable for the deposition of metallic particles at their surface . The cluster growth is subject of this thesis. The binding of metal complexes to S-layers of Bacillus sphaericus and Sporosarcina ureae and their subsequent reduction leads to the formation of regularly arranged platinum or palladium cluster arrays on the biomolecular template. A heterogeneous nucleation mechanism is proposed for this process consisting of the binding of metal complexes and their subsequent reduction. The kinetics of the process and the binding of the complexes to the protein are characterized by UV/VIS spectroscopy. This thesis focuses on structural investigations by means of transmission electron microscopy, electron holography, scanning force microscopy, image analysis, and image processing. Preferred cluster-deposition sites are determined by correlation averaging. A more precise determination and quantification is obtained by Multivariate Statistical Analysis. Furthermore a method for the electron beam induced formation of highly-ordered metallic cluster arrays in the transmission electron microscope and a fast screening method for surface layers of Gram-positive bacteria are presented. / Bakterielle Zellhüllenproteine (S-Layer) eignen sich durch ihre Fähigkeit zur Selbstassemblierung zu zweidimensionalen Kristallen und durch ihre besonderen chemischen und strukturellen Eigenschaften zur Abscheidung regelmäßiger metallischer Partikel auf ihrer Oberfläche. In dieser Arbeit wird das Clusterwachstum auf S-Layern untersucht. Die Anbindung von Metallkomplexen an S-Layer von Bacillus sphaericus und Sporosarcina ureae und deren Reduktion führt zur Abscheidung periodisch angeordneter metallischer Platin- bzw. Palladiumcluster auf dem Biotemplat. Für diese Clusterbildung wird ein heterogener Keimbildungsmechanismus vorgeschlagen, bestehend aus Komplexanbindung und Reduktion. Die Bestimmung der Prozeßkinetik und die Charakterisierung der Anbindung der Komplexe an das Protein erfolgt mittels UV/VIS-Spektroskopie. Den Schwerpunkt dieser Arbeit bilden strukturelle Untersuchungen mit Hilfe der Transmissionselektronenmikroskopie, der Elektronenholographie, der Rasterkraftmikroskopie und der Bildanalyse und Bildverarbeitung. Durch Korrelationsmittelung werden Strukturinformationen gewonnen, die eine Bestimmung der lateral bevorzugten Clusterpositionen ermöglichen. Für die auf S-Layern erzeugten Clusterarrays wird die Belegung der einzelnen Positionen mittels Multivariater Statistischer Analyse genauer quantifiziert. Außerdem werden eine Methode zur Erzeugung hochgeordneter metallischer Partikelarrays unter dem Einfluß des Elektronenstrahles im Transmissionselektronenmikroskop und eine Methode zum schnellen Test Gram-positiver Bakterienstämme auf die Existenz von S-Layern vorgestellt.
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U(VI) bioaccumulation by Paenibacillus sp. JG-TB8 and Sulfolobus acidocaldariusReitz, Thomas 01 February 2012 (has links) (PDF)
In this thesis, the interactions of U(VI) with one representative each of the domains Bacteria (Paenibacillus sp. JG TB8) and Archaea (Sulfolobus acidocaldarius) are compared. We demonstrate that at highly acidic conditions (pH ≤ 3), U(VI) is bound to cells of the both strains exclusively via organic phosphate groups. In contrast to this, the U(VI) complexation modes differ between the studied strains at moderate acidic conditions. These differences are assigned to the different cell wall structures of both strains as well as to their different physiological characteristics. We also demonstrate that the aeration conditions can strongly influence the uranium accumulation of facultative anaerobic microorganisms at moderate acidic pH conditions. This finding could clearly be assigned to the dependency of the intrinsic phosphatase activity on the aeration conditions.
The second part of this thesis deals with the outermost surface layer (SlaA-layer) of S. acidocaldarius. It was shown that this surface protein is not involved in the U(VI) complexation at highly acidic conditions, covering the physiological pH optimum of S. acidocaldarius. Hence the SlaA layer does not provide a protective function against U(VI) to the cells of this acidophilic archaeon. However, we demonstrated that purified SlaA-layer ghosts (i.e. empty cell sacculi) efficiently interact with gold ions and are a good macromolecular template for the formation of magnetic gold nanoparticles. / In dieser Doktorarbeit werden die Wechselwirkungen von U(VI) mit je einem Vertreter der Bakterien (Paenibacillus sp. JG TB8) und Archeen (Sulfolobus acidocaldarius) verglichen. Wir konnten zeigen, dass U(VI) im sehr sauren Milieu (pH ≤ 3) ausschließlich durch organische Phosphatgruppen an die Zellen beider Stämme gebunden ist. Im Gegensatz dazu unterscheiden sich die Mechanismen der U(VI)-Komplexierung beider untersuchter Stämme bei mäßig sauren Bedingungen voneinander. Diese Unterschiede basieren auf den unterschiedlichen Zellwandstrukturen und physiologischen Eigenschaften beider Stämme. Wir konnten außerdem zeigen, dass die atmosphärischen Bedingungen die Urankomplexierung durch fakultativ anaerobe Mikroorganismen bei mäßig sauren Bedingungen stark beeinflussen kann. Dieses Ergebnis konnte eindeutig auf die von den atmosphärischen Bedingungen-abhängige, enzymatische Aktivität der zelleigenen Phosphatase zurückgeführt werden.
Der zweite Teil dieser Arbeit beschäftigt sich mit der äußeren Oberflächenschicht (SlaA-layer) von S. acidocaldarius. Es konnte gezeigt werden, dass dieses Oberflächenprotein nicht an der U(VI)-Komplexierung bei stark sauren pH, welcher dem physiologischen pH Optimum von S. acidocaldarius entspricht, beteiligt ist. Damit stellt der SlaA-layer keinen Schutz gegen Uran für die Zellen dieses azidothermophilen Archaeons dar. Allerdings konnten wir zeigen, dass isolierte „SlaA-layer ghosts“ (d.h. leere Zellhüllen) mit Goldionen interagieren und sich daher als makromolekulares Template für die Herstellung magnetischer Gold Nanopartikel eignen.
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