Global ETD Search

21	Evasion and Attack: Structural Studies of a Bacterial Albumin-binding Protein and of a Cephalosporin Biosynthetic Enzyme Lejon, Sara January 2008 (has links) <p>This thesis describes the crystal structures of two proteins in the context of combatting bacterial infections. The GA module is a bacterial albumin-binding domain from a surface protein expressed by pathogenic strains of the human commensal bacterium <i>Finegoldia magna</i>. The structure of the GA module in complex with human serum albumin (HSA) provides insights into bacterial immune evasion, where pathogenicity is acquired by the bacterial cell through the ability to coat (and disguise) itself with serum proteins. The structure shows binding of the GA module to HSA in the presence of fatty acids, and reveals interactions responsible for the host range specificity of the invading bacterium. The complex resulting from binding of the GA module to HSA readily forms stable crystals that permit structural studies of drug binding to HSA. This was exploited to study the specific binding of the drug naproxen to the albumin molecule.</p><p>Antibiotics play a major role in controlling infections by attacking invading bacteria. The enzyme deacetylcephalosporin C acetyltransferase (DAC-AT) catalyses the last step in the biosynthesis of the beta-lactam antibiotic cephalosporin C, one of the clinically most important antibiotics in current use. The enzyme uses acetyl coenzyme A as cofactor to acetylate a biosynthetic intermediate. Structures of DAC-AT in complexes with reaction intermediates have been determined. The structures suggest that the acetyl transfer reaction proceeds through a double displacement mechanism, with acetylation of a catalytic serine by the cofactor through a suggested tetrahedral transition state, followed by acetyl transfer to the intermediate through a second suggested tetrahedral transition state. The structure of DAC-AT yields valuable information for the continued study of cephalosporin biosynthesis in the context of developing new beta-lactam compounds.</p> human serum albumin GA module albumin-binding Finegoldia magna cephalosporin C antibiotic beta-lactam biosynthesis Acremonium chrysogenum X-ray crystallography Structural biology Strukturbiologi
22	Evasion and Attack: Structural Studies of a Bacterial Albumin-binding Protein and of a Cephalosporin Biosynthetic Enzyme Lejon, Sara January 2008 (has links) This thesis describes the crystal structures of two proteins in the context of combatting bacterial infections. The GA module is a bacterial albumin-binding domain from a surface protein expressed by pathogenic strains of the human commensal bacterium Finegoldia magna. The structure of the GA module in complex with human serum albumin (HSA) provides insights into bacterial immune evasion, where pathogenicity is acquired by the bacterial cell through the ability to coat (and disguise) itself with serum proteins. The structure shows binding of the GA module to HSA in the presence of fatty acids, and reveals interactions responsible for the host range specificity of the invading bacterium. The complex resulting from binding of the GA module to HSA readily forms stable crystals that permit structural studies of drug binding to HSA. This was exploited to study the specific binding of the drug naproxen to the albumin molecule. Antibiotics play a major role in controlling infections by attacking invading bacteria. The enzyme deacetylcephalosporin C acetyltransferase (DAC-AT) catalyses the last step in the biosynthesis of the beta-lactam antibiotic cephalosporin C, one of the clinically most important antibiotics in current use. The enzyme uses acetyl coenzyme A as cofactor to acetylate a biosynthetic intermediate. Structures of DAC-AT in complexes with reaction intermediates have been determined. The structures suggest that the acetyl transfer reaction proceeds through a double displacement mechanism, with acetylation of a catalytic serine by the cofactor through a suggested tetrahedral transition state, followed by acetyl transfer to the intermediate through a second suggested tetrahedral transition state. The structure of DAC-AT yields valuable information for the continued study of cephalosporin biosynthesis in the context of developing new beta-lactam compounds. human serum albumin GA module albumin-binding Finegoldia magna cephalosporin C antibiotic beta-lactam biosynthesis Acremonium chrysogenum X-ray crystallography Structural biology Strukturbiologi
23	Characterization of the fusion protein mNG-Aβ1-42 as a fluorescence reporter probe for amyloid structure Fredén, Linnéa January 2020 (has links) Alzheimer’s Disease, also called AD, is a horrible, degenerative brain disease that more than 35 million people over the world have. Today, there is no cure for this disease, only treatments that are temporarily relieving the symptoms. The two proteins that is thought to be the main cause of AD is amyloid β (Aβ) and tau. Previously, people have tried studying Aβ in vivo using green fluorescent protein fusion together with Aβ. However, this is difficult since the aggregation of Aβ will lead to loss of fluorescence. This study aimed to crystallize the fusion protein mNG-A β1-42 and to investigate its properties as a molecular fluorescent Aβ-amyloid specific probe. Dynamic light scattering (DLS) was used to confirm that the majority of the protein was not in the form of soluble aggregates. The DLS experiments were followed by several rounds of crystallization trials. Initial screening and the subsequent narrowing down of potential conditions where mNG-Aβ1-42 could form crystals. Several staining experiments were conducted as well, including staining brain tissue from mouse with both Swedish and Arctic mutation, from human patients with sporadic AD and from human patients with AD with the Arctic mutation. The DLS experiments showed that the protein used in the crystallization experiments mostly consisted of molecular particles of the same radius. However, there was clear evidence of some larger species present that could have been a potential problem for crystallization. Crystallization experiments suggested that PEG 8000 was the most promising precipitant amongst other conditions identified for crystallization of mNG-Aβ1-42. However, the study was ultimately unsuccessful in developing crystals of sufficient high quality for diffraction studies to commence. The staining experiments demonstrated that mNG-Aβ1-42 could bind both by itself and with another amyloid probe, Congo red, and with antibodies in brain tissue from mouse with both Swedish and Arctic mutation, from human patients with sporadic AD and from human patients with AD with the Arctic mutation. In conclusion, several characteristics of mNG-Aβ1-42 were revealed in this study. Alzheimer’s Disease (AD) Amyloids Aβ fusion protein mNeonGreen mNG-Aβ1-42 Crystallization mouse brain tissue human brain tissue amyloid fluorescent probes Structural Biology Strukturbiologi
24	Characterization of Giant Proteins from Lactobacillus kunkeei Schol, Martin January 2020 (has links) Lactobacillus kunkeei is the most common and dominant bacterium in the honey stomach of honeybees. L. kunkeei has been isolated from honeybees all over the world. Genome sequencing has identified 5 genes for exceptionally large proteins in the genome of L. kunkeei. These proteins do not show any similarity to sequences of proteins with a known structure. These giant proteins all have a conserved region of 60 amino acids in their C-terminus. This conservation led to the hypothesis that the C-terminal domains of the giant proteins are important for their function with possibly a role in the attachment to the cell wall. In this study, a total of eight different constructs were made for two of these giant proteins. The boundaries for the constructs were determined based on bioinformatic predictions. The eight constructs all have different start positions and all end at the very C-terminal end of the protein. These constructs were cloned into an expression vector. One of the full-length giant protein was cloned into an expression vector as well. The C-terminal constructs and the full-length proteins were recombinantly produced in Escherichia coli. Expression of six C-terminal constructs was observed and an attempt was made to purify two of the C-terminal constructs. Expression of the full-length giant protein was observed as well and purification was attempted. Neither the C-terminal constructs nor the full-length giant protein could be purified at full length. The results for the C-terminal constructs show that no folded C-terminal domain has been found for the giant proteins. A purified protein construct of the N-terminal of one of the giant proteins was available. This protein was analyzed using biophysical techniques. Circular dichroism was used to test the thermal stability. The construct did not refold after being thermally denatured. Circular dichroism measurements indicated that the N-terminal construct is composed of a mixture of α-helices and ß-sheets. Small-angle X-ray scattering data indicated that the N-terminal construct had an elongated shape with knot-like parts. Protein crystals have been obtained for the N-terminal construct and these will be analyzed using X-ray diffraction. structural biology protein expression protein purification Lactobacillus kunkeei L. kunkeei small angle X-ray scattering SAXS circular dichroism CD honey bee honey crop extracellular protein Structural Biology Strukturbiologi
25	Towards time-resolved cryo-EM of SARS-CoV-2 replication-transcription complex and Staphylococcus aureus DNA gyrase Králová, Anna January 2023 (has links) Time-resolved cryo-EM has already provided ground-breaking discoveries in various fields, including structural biology, biochemistry, and drug development. Compared to traditional structural biology methods where mostly stabilized conformations are reconstructed, the main advantage of time-resolved cryo-EM is its ability to capture dynamic processes in biological samples at near-atomic resolution, which allows for studying biological structures as they change and interact in real-time. In this project, I focused on the expression and purification of the individual proteins of two dynamic molecular complexes – Staphylococcus aureus (S. aureus) DNA gyrase and Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) replication-transcription complex – and attempted to assemble them into their functional forms for cryo-EM imaging. Both of these complexes are interesting drug targets as they play an essential role in nucleic acid replication. The function of DNA gyrase is to modulate DNA supercoiling, facilitate DNA replication, and resolve intertwined DNA molecules. The replication-transcription complex of SARS-CoV-2 comprises, among other proteins, the RNA-dependent RNA polymerase, which, together with non-structural proteins 7 and 8, is responsible for the replication of the viral genome. There are still many questions about the underlying mechanisms of these key processes, and time-resolved cryo-EM studies will provide valuable information to advance our understanding of them. Here I present expression and purification protocols for S. aureus DNA gyrase subunits A and B and SARS-CoV-2 non-structural proteins 7, 8 and 12. DNA gyrase subunits A and B were expressed in Escherichia coli (E. coli) and purified in several steps, including affinity chromatography (His-Trap), ion exchange chromatography (IEX) and size exclusion chromatography (SEC). Despite many challenges with gyrase A precipitation, I obtained enough of both subunits for the intended cryo-EM. Different strategies to assemble them into a functional tetramer were tested but did not result in the expected outcome. The gained knowledge about the behaviour of the subunits in solution will serve as a basis for further optimization of the protocols before the assembly of the complex can be attempted again. Non-structural proteins 7 and 8 were expressed in E. coli as a polyprotein and successfully purified using His-Trap and SEC. I obtained a great amount of the polyprotein and established a protocol for its cleavage. Nsp12 was expressed using the baculovirus-insect cell expression system. The immunofluorescence assay data showed that the tested lipofection protocol works, and nsp12 is being produced in sufficient quantities. This result provides a solid base for further experiments to establish a purification method and assemble the nsp12-nsp7-nsp8 complex for cryo-EM imaging. time-resolved cryo-EM DNA gyrase SARS-CoV-2 replication-transcription complex protein purification Cell and Molecular Biology Cell- och molekylärbiologi Structural Biology Strukturbiologi
26	The perfect wing, The perfect trade-off? : What implements the main selection pressure on wing morphology? MacDonald, Emme January 2023 (has links) Selection pressure is a constant force in evolution, pushing birds and their wings towards an optimal shape and structure, were increasing performance, and minimizing the costs is central. But even though the science of aerodynamics can provide calculations of the optimal construction for the wing in different situations this rarely directly correspond to what is observed in nature. Since the optima are not the same for all birds due to different specifications and ecology this optimum becomes harder to determine and different functions can even have different optima, resulting in selection conflict. In the genius of birds there is an immense variation between species and their wings in everything from size, shape, and function. The aim of this study is to investigate how wing morphology over a large phylogeny of bird species correlates to migration and habitat/ecology. Many studies have been done focusing on the effect of migration on the wing morphology, and some have been done focusing on other parameters such as display or daily usage. But by including the bird’s ecology and habitat related information with migration and morphology and looking at the selection from a broad perspective, can we uncover something more? The morphology of the wing cannot provide a perfect optimum for all circumstances since they require different specifications. What then, has the largest impact on the wing’s morphology? And does the relative length of the tail provide any correlations with its habitat and performance? 1185 birds of 137 species were caught at Ottenby, Öland and information on age, weight, sex, and tail length was collected for each individual bird. Photographs were taken of the back of the bird with the left wing outstretched 90 degrees from the body and analyzed in ImageJ to calculate aspect ratio and wing loading. Data on migration distance, foraging behavior, diet, and habitat density was then added for each of the species. Mean values of all parameters was calculated on species level creating a strong dataset with 137 data points. The species mean values dataset was used to test the interspecific effects and the dataset with all individuals was used to test intraspecific effects. ANOVAs, ANCOVAs, correlations tests and random slopes mixed models were performed revealing significant connections between wing morphology, migration, and habitat density. Correlations could also be observed between wing morphology, diet, and foraging behavior. Habitat density revealed the highest correlation with wing morphology, demonstrating a greater significance than migration and the other parameters. Effects that at first sight looked significant could later be excluded as they turned out to be dependent on other variables. The study therefore also highlights the importance of including alternative parameters for reliable conclusions. Bird wing morphology migration habitat aspect ratio wing loading Ecology Ekologi Evolutionary Biology Evolutionsbiologi Structural Biology Strukturbiologi Developmental Biology Utvecklingsbiologi Zoology Zoologi
27	Computational Analysis of Molecular Recognition Involving the Ribosome and a Voltage Gated K+ Channel Andér, Martin January 2009 (has links) Over the last few decades, computer simulation techniques have been established as an essential tool for understanding biochemical processes. This thesis deals mainly with the application of free energy calculations to ribosomal complexes and a cardiac ion channel. The linear interaction energy (LIE) method is used to explore the energetic properties of the essential process of codon–anticodon recognition on the ribosome. The calculations show the structural and energetic consequences and effects of first, second, and third position mismatches in the ribosomal decoding center. Recognition of stop codons by ribosomal termination complexes is fundamentally different from sense codon recognition. Free energy perturbation simulations are used to study the detailed energetics of stop codon recognition by the bacterial ribosomal release factors RF1 and RF2. The calculations explain the vastly different responses to third codon position A to G substitutions by RF1 and RF2. Also, previously unknown highly specific water interactions are identified. The GGQ loop of ribosomal RFs is essential for its hydrolytic activity and contains a universally methylated glutamine residue. The structural effect of this methylation is investigated. The results strongly suggest that the methylation has no effect on the intrinsic conformation of the GGQ loop, and, thus, that its sole purpose is to enhance interactions in the ribosomal termination complex. A first microscopic, atomic level, analysis of blocker binding to the pharmaceutically interesting potassium ion channel Kv1.5 is presented. A previously unknown uniform binding mode is identified, and experimental binding data is accurately reproduced. Furthermore, problems associated with pharmacophore models based on minimized gas phase ligand conformations are highlighted. Generalized Born and Poisson–Boltzmann continuum models are incorporated into the LIE method to enable implicit treatment of solvent, in an effort to improve speed and convergence. The methods are evaluated and validated using a set of plasmepsin II inhibitors. computer simulations molecular dynamics ligand binding binding free energy linear interaction energy codon recognition translation termination release factor voltage gated potassium ion channel Kv1.5 Structural biology Strukturbiologi Biochemistry Biokemi
28	Structural and Functional Studies of Giant Proteins in Lactobacillus kunkeei Ågren, Josefin January 2019 (has links) Lactobacillus kunkeei is one of the most abundant bacteria within the honey crop of the honey bee. Genome sequencing of L. kunkeei isolated from honey bees all over the world showed several genes unique for L. kunkeei. Among these orphan genes, an array of four to five highly conserved genes coding for giant extracellular proteins were found. Cryogenic electron microscopy imaging of a giant-protein preparation from L. kunkeei A00901 showed an overall structure similar to a long string with a knot at the end. Further analysis showed high similarity between the different giants at the N-terminus, and secondary structure predictions showed that the same region was rich in β-sheets. These results, combined with the knowledge of other large extracellular proteins, led to the hypothesis that the “knot” domain is located at the N-terminus and that these proteins are used by the cell to latch on to the intestine lining or other cells in the honey crop. In this study, predictions were made to locate the N-terminal domains of two of these giant proteins. Four different constructs were made for each protein, where three constructs were designed for expression and purification of the N-terminal domain with different end-positions, and one construct was for a predicted β-solenoid domain located downstream from the N-terminal domain. The protein constructs were recombinantly produced in E. coli, and three of the N-terminal constructs from both proteins were purified. Thermal stability was tested using nano differential scanning fluorimetry (nanoDSF), Thermofluor, and circular dichroism (CD), which all showed characteristic melting curves at low melting temperatures, ranging from 33 °C to 44 °C, for all three constructs. During CD measurements, all three constructs showed refolding after thermal denaturation and a higher abundance of antiparallel β-sheets over α-helices. Looking at the protein structure, small angle X-ray scattering data indicated that all three proteins formed elongated structures. These results indicate that a folded domain has been found for both proteins. Although, further analysis will be required to determine the boundaries of the N-terminal domains, and to elucidate if these domains have anything to do with ligand binding and the L. kunkeei ability to latch onto the honey crop. structural biology protein expression Lactobacillus kunkeei L. kunkeei small angle X-ray scattering SAXS circular dichroism CD thermofluor nano differential scanning fluorimetry nanoDSF honey bee honey crop extracellular protein Structural Biology Strukturbiologi
29	Purification, functional characterization and crystallization of the PerR peroxide sensor from Saccharopolyspora erythraea Elison Kalman, Grim January 2019 (has links) This report summarizes the work on the cloning, expression, and purification of PerR, a metal sensing regulator from Saccharopolyspora erythraea and the subsequent characterization using small angle X-ray scattering and other biochemical methods. The report aims to provide an insight into prokaryotic metal homeostasis, provide a better understanding of how PerR works and provide valuable information for the continued work on the crystallization of PerR. structural biology cell culture protein expression genetic engineering spectroscopy X-ray crystallography small angle X-ray scattering SAXS transcription factor PerR metal binding antibiotics Saccharopolyspora erythraea S. erythraea soil bacterium actinobacteria actinomycetes oxidative stress peroxide stress structure determination characterization stabilization peroxide sensor iron sensor manganese sensor metalloprotein metal ion homeostasis metal ion prokaryotic strukturbiologi cellodling proteinuttryck genteknik spektroskopi röntgenkristallografi småvinkel-röntgenspridning SAXS transkriptionsfaktor PerR metallbindande antibiotika Saccharopolyspora erythraea S. erythraea jordartsbakterie Aktinobakterier Actinobacteria Actinomycetes oxidativ stress peroxid stress strukturbestämning karaktärisering stabilisering peroxidsensor järnsensor mangansensor metalljonshomeostas metalljoner prokaryot Structural Biology Strukturbiologi
30	Searching for novel protein-protein specificities using a combined approach of sequence co-evolution and local structural equilibration Nordesjö, Olle January 2016 (has links) Greater understanding of how we can use protein simulations and statistical characteristics of biomolecular interfaces as proxies for biological function will make manifest major advances in protein engineering. Here we show how to use calculated change in binding affinity and coevolutionary scores to predict the functional effect of mutations in the interface between a Histidine Kinase and a Response Regulator. These proteins participate in the Two-Component Regulatory system, a system for intracellular signalling found in bacteria. We find that both scores work as proxies for functional mutants and demonstrate a ~30 fold improvement in initial positive predictive value compared with choosing randomly from a sequence space of 160 000 variants in the top 20 mutants. We also demonstrate qualitative differences in the predictions of the two scores, primarily a tendency for the coevolutionary score to miss out on one class of functional mutants with enriched frequency of the amino acid threonine in one position. Biotechnology Bioinformatics Molecular Structure Protein Conformation Computing Methodologies Protein-protein interaction Binding affinity Mutation analysis Amino acid mutation in-silico binding affinity prediction Two-component regulatory system Histidine Kinase Response Regulator Prediction PhoQ PhoP Phosphatase Bioinformatics and Systems Biology Bioinformatik och systembiologi Structural Biology Strukturbiologi Bioinformatics (Computational Biology) Bioinformatik (beräkningsbiologi)

Search results