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Investigating the methane producing pathway in lab-scale biogas reactors subjected to sequential increase of ammonium and daily acetate-pulsingMoberg, Sofia January 2020 (has links)
Syntrophic acetate oxidizing bacteria convert acetate into hydrogen and carbon dioxide and through the mutualistic syntrophic partnership with methanogens the products are further converted to methane in biogas processes operating at high ammonia concentrations. There is very little known about SAOBs, only five have been characterized and had their genome analyzed. The aim of this project was to gain further knowledge about the methane producing pathway of SAOBs with a proteomic approach. Proteins were extracted from biogas sludge with a phenol-based approach and trypsin digestion and peptide recovery were performed using the Suspension Trapping method. Measurement of the peptide content was made with LC-MS/MS. The peptide profiles obtained were screened for the proteins expressed of the mesophilic SAOB Syntrophaceticus schinkii. The data supports earlier suggestions that it utilizes the Wood-Ljungdahl pathway for hydrogen production. Furthermore, the peptide profile revealed that enzymes for the glycine reductase complex and the glycine cleavage system were expressed during high ammonia concentration, indicating a potential role of these enzymes in the methane producing pathway. However, due to partial failure of the sample preparation for mass spectrometry measurements no quantification conclusions could be made. A discussion on how to further improve sample preparation methods as well as how to access the proteome to a large extent is presented.
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Optimizing signal peptides for expression of recombinant antibodies in HEK293 cellsMyhrinder, Gustav January 2020 (has links)
Monoclonal antibodies are well-established as a therapeutic in the biopharmaceutical market, targeting a variety of diseases and with 79 approved products by the United States Food and Drug Administration in December 2019. Therapeutic monoclonal antibodies are commonly produced as recombinant proteins in mammalian cell lines, due to their capacity of post-translational modifications, most notably glycosylation. Furthermore, an identified bottleneck within the production of recombinant proteins is the translocation of nascent proteins from the cytosol into the lumen of the endoplasmic reticulum. The signal peptide, which is located at the N-terminal of nascent proteins, plays a central role in the process of protein secretion. Several studies have shown that optimization of signal peptides is a crucial step for attempting to achieve increased expression of recombinant antibodies in mammalian systems. The aim of this study was to evaluate the expression of three human recombinant antibodies in Human Embryonic Kidney 293 (HEK293) cells by evaluating 16 different signal peptide combinations, consisting of eight heavy chain (HC) and two light chain (LC) signal peptides. The impact goal was an efficient secretion of recombinant antibodies, and thus lower production cost of recombinant antibodies in HEK293 cells. First, 16 HC and LC signal peptide plasmid constructs were generated for each of the three recombinant antibodies. Thereafter, transient gene expression in HEK293 cells were performed at three independent experiments. Finally, the antibody titers were quantified using Biacore concentration analysis. The produced antibody titers for the three studied recombinant antibodies were highly dependent on the used signal peptides. Interestingly, the evaluated HC and LC signal peptide combinations resulted in 3 times higher and 2 times higher antibody titers compared to the original signal peptides used by the Drug Discovery and Development platform at Science for Life Laboratory, for two of the studied antibodies respectively. The results presented in this report further demonstrates the necessity to evaluate signal peptides in order to achieve increased expression of recombinant antibodies in mammalian systems.
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Modulation of a model ligand-gated ion channel by amphetamine derivativesKarlsson, Emelia January 2022 (has links)
Pentameric ligand-gated ion channels are critical mediators of electrochemical signal transduction in neurons and other excitable cells, causing them to be important targets of psychoactive drugs. Structural data for these complex proteins are limited, particularly among eukaryotic family members and for the functionally critical open state. These data limitations cause knowledge gaps regarding the mechanisms of ion channel opening, gating, and modulation. However, a newly discovered bacterial family member, known as sTeLIC, shares numerous structural features with its eukaryotic relatives in our central nervous system. A recently solved electron microscopy structure depicts sTeLIC in an apparent open state with binding pockets in its extracellular domain, compatible with binding a drug with structural similarities to amphetamines, like the 4-bromoamphetamine. This project aims to provide the first structure-function evidence for direct modulation of a pentameric ligand-gated ion channel by an amphetamine. The two most essential tools used in this project to examine the effects of 4-bromoamphetamine on sTeLIC were Xenopus laevis oocytes and two-electrode voltage-clamp. These tools were necessary for the collection of gating and modulation data. Ion channel activities can be analysed by clamping sTeLIC injected Xenopus laevis oocytes into the two-electrode voltage-clamp since it can artificially control the membrane voltage of oocytes. Modulation data show that 4-bromoamphetamine is a bimodal allosteric potentiator, as well as an allosteric agonist. Residues Y104 and W75, located in the binding pocket, were selected by comparing the published open state model with an AlphaFold-generated non-conducting model. Mutating these into valine or alanine reduces the potentiation. One explanation may be that removing tyrosine's aromatic ring complicates retaining essential interactions in the binding pocket while swapping tryptophan for smaller residues could make it easier for the drug to stabilise the closed state.
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Molecular Mechanisms of Endophilin B1-Bax Macromolecular Complexes in Membrane Permeabilization and Cell DeathKollberg Hedström, Tobias January 2022 (has links)
A crucial step during apoptosis is the accumulation of the pro-apoptotic protein Bax on the mitochondria where it triggers permeabilization of the outer membrane. This causes the release of cytochrome c into the cytosol and is considered a point of no return in programmed cell death. Endophilin B1, also known as Bax-interacting factor 1 (Bif-1) stimulates mitochondrial recruitment of Bax during apoptosis and loss of endophilin B1 is noted in many cancer types. Despite the importance of their interaction its role and function during cell death remains unclear. To examine the molecular mechanism behind their interaction this project aimed at solving the structure of endophilin B1-Bax complexes when bound to membrane mimicking platforms known as nanodiscs (NDs). NDs are composed of a lipid bilayer held together by a membrane scaffolding protein (MSP) that encircles the bilayer creating a disc-shaped structure. By designing NDs that resembles the mitochondrial outer membrane (MOM), this study intended to stimulate complex formation and stable binding to nanodiscs with the ambition of visualising their interaction using Cryo-EM. Due to difficulties of expressing and purifying Bax as well as time consuming optimization of ND assembly the final goal could not be reached. By establishing an optimized protocol for NDs using the MSP variant MSP2N2 and 1,2-dioleoyl-sn-glycero-3-phospho-L-serine (DOPS) lipids as well as identifying challenges of expressing and purifying Bax this study lays ground for future structural studies that aims at elucidating the molecular mechanism behind the interaction.
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A holistic approach to understanding CAZy families through reductionist methodsEklöf, Jens January 2009 (has links)
In a time when the amount of biological data present in the public domain is becoming increasingly vast, the need for good classification systems has never been greater. In the field of glycoscience the necessity of a good classification for the enzymes involved in the biosynthesis, modification and degradation of polysaccharides is even more pronounced than in other fields. This is due to the complexity of the substrates, the polysaccharides, as the theoretical number of possible hexa-oligosaccharides from only hexoses exceeds 1012 isomers! An initiative to classify enzymes acting on carbohydrates began around 1990 by the French scientist Bernard Henrissat. The resulting database, the Carbohydrate Active enzymes database (CAZy), classifies enzymes by sequence similarity into families allowing the inference of structure and catalytic mechanism. What CAZy does not provide however, are means to understand how members of a family are related, and in what way they differ from each other. The top-down approach used in this thesis, combining phylogenetic analysis of whole CAZy families, or sub-families, with structural determinations and detailed kinetic analysis allows for exactly that. Finding determinants for transglycosylation versus hydrolysis within the xth gene product family of GH16 as well as restricting the hydrolytic enzymes to a well defined clade are integral parts of paper I. In paper II a new bacterial sub-clade within CE8 was discovered. The structural determination of theEscherichia coli outer membrane lipoprotein YbhC from from the new sub-clade explained the difference in specificity. The information provided in the two papers of this thesis gives a better understanding of the development of different specificities of diverse CAZY families as well as it aids in future gene product annotations. Furthermore this work has begun to fill the white spots uncovered in the phylogenetic trees.
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Molecular modelling - understanding and prediction of enzyme selectivity.Fransson, Linda January 2009 (has links)
Molecular modelling strategies for evaluation of enzyme selectivity wereinvestigated with a focus on principles of how molecular interactionscould be evaluated to provide information about selectivity. Althoughmolecular modelling provides tools for evaluation of geometrical andenergy features of molecular systems, no general strategies for evaluationof enzyme selectivity exist. Geometrical analyses can be based uponinspection and reasoning about molecular interactions, which provide aneasily accessible way to gain information, but suffer from the risk of biasput in by the modeller. They can also be based on geometrical features ofmolecular interactions such as bond lengths and hydrogen-bond formation.Energy analyses are appealing for their modeller independenceand for the possibility to predict not only stereopreference, but also itsmagnitude.In this thesis, four examples of enantio- or regioselective serinehydrolase-catalysed reaction systems are presented together with developedmodelling protocols for explanation, prediction or enhancement ofselectivity. Geometrical as well as energy-based methodology were used,and provided an understanding of the structural basis of enzymeselectivity. In total, the protocols were successful in making qualitative explanationsand predictions of stereoselectivity, although quantitative determinationswere not achieved.
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Effects of antibody labeling chemistry on assays developed for the Gyrolab immunoassay platformDencker, Julia January 2021 (has links)
The aim of this project was to make a comparison of the effects of antibody labeling chemistries on assays developed for the Gyrolab immunoassay platform. One of the labeling techniques was a heterogenous labeling technique targeting amino groups on the antibody. The other labeling technique was a site-specific labeling technique targeting the conserved Fc-glycan at the aspargine 297 residue on the IgG molecule. The site-specific labeling was performed using a kit from Genovis called GlyCLICK. The two labeling techniques were compared on four different assays developed for the Gyrolab platform. The assays tested in this project were two anti-drug antibody assays, a pharmacokinetics assay, a polyclonal antibody assay, and a monoclonal antibody assay. The drug tolerance was tested for the anti-drug antibody assays, resulting in better drug tolerance for reagents labeled with amino conjugation for the Humira assay with incubation overnight. A confirmatory analysis, testing the inhibition of negative control with addition of unlabeled drug in the Master Mix, was performed. This resulted in small differences in the inhibition between the different reagents, except for Keytruda on Gyrolab Bioaffy 200, for which the GlyCLICK labeled reagents led to a lower inhibition of the negative control. For all the assays the effects on signal to background ratio and limit of detection was investigated. The greatest advantages of GlyCLICK on the signal to background was observed for anti-drug antibody Keytruda assay and polyclonal antibody assay. For the polyclonal antibody assay, the results indicated potentially reduced need for the polishing step and for two wash solutions after addition of the detect reagent.
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Oligonucleotide Complexes with Cell-Penetrating Peptides : Structure, Binding, Translocation and Flux in Lipid MembranesFerreira Vasconcelos, Luis Daniel January 2014 (has links)
The ability of cell-penetrating peptides to cross plasma membranes has been explored for various applications, including the delivery of bioactive molecules to inhibit disease-causing cellular processes. The uptake mechanisms by which cell-penetrating peptides enter cells depend on the conditions, such as the cell line the concentration and the temperature. To be used as therapeutics, each novel cell-penetrating peptide needs to be fully characterized, including their physicochemical properties, their biological activity and their uptake mechanism. Our group has developed a series of highly performing, non-toxic cell-penetrating peptides, all derived from the original sequence of transportan 10. These analogs are called PepFects and NickFects and they are now a diverse family of N-terminally stearylated peptides. These peptides are known to form noncovalent, nano-sized complexes with diverse oligonucleotide cargoes. One bottleneck that limits the use of this technology for gene therapy applications is the efficient release of the internalized complexes from endosomal vesicles. The general purpose of this thesis is to reveal the mechanisms by which our in house designed peptides enter cells and allow the successful transport of biofunctional oligonucleotide cargo. To reach this goal, we used both biophysical and cell biology methods. We used spectroscopy methods, including fluorescence, circular dichroism and dynamic light scattering to reveal the physicochemical properties. Using confocal and transmission electron microscopy we observed and tracked the internalization and intracellular trafficking. Additionally we tested the biological activity in vitro and the cellular toxicity of the delivery systems. We conclude that the transport vectors involved in this study are efficient at perturbing lipid membranes, which correlates with their remarkable capacity to transport oligonucleotides into cells. The improved and distinct capacities to escape from endosomal vesicles can be the result of their different structures and hydrophobicity. These findings extend the knowledge of the variables that condition intracellular Cell-penetrating peptide mediated transport of nucleic acids, which ultimately translates into a small step towards successful non-viral gene therapy.
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Development of a cell-based assay for measuring the NAD levels in polyphenol treated cellsJöe, Melissa January 2020 (has links)
Glaucoma is one of the leading causes of vision loss in the world and it is characterized by the dysfunction of retinal ganglion cells (RGCs). An early pathomechanism of glaucoma is the degeneration of the axons of RGCs and finding new treatments that could prevent axon degeneration is of great interest. Increasing the concentration of coenzyme nicotinamide adenine dinucleotide (NAD) has been shown to be axon protective in a number of neurodegenerative systems. Increasing NAD could potentially be achieved by increasing the catalytic properties of the terminal enzyme involved in the cytosolic production of neuronal NAD, nicotinamide mononucleotide adenylyltransferase 2 (NMNAT2). NMNAT2 is thus an ideal therapeutic target. Polyphenol A (PA), which is a polyphenol that will not be disclosed, has been demonstrated to be NAD-boosting through positive modulation of NMNAT2. The aim was to develop a cell-based assay for screening PA and 12 novel analogues of PA for their NAD-boosting effects in brain cortex, retinal and liver cells isolated from C57BL/6J mice. The protocol involved using a bioluminescence assay for which optimization of variables such as cell concentration, substrate (nicotinamide) concentration, PA concentration and incubation time was performed. The method development resulted in a one-day protocol for testing PA and its analogues in cortical cells. PA and several of its analogues exhibited NAD-boosting effects. This protocol along with the results from the screening can be further used for the development of novel drugs that could prevent glaucoma and other axon and neurodegenerations.
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Regulation of Plant Defense Genes Against Bacterial PathogensSjöström, Jenny January 2021 (has links)
Sjukdom på grödor orsakad av bakterier kan bidra till ekonomiska förluster för bönder samt brist på mat, därför är det viktigt att utveckla nya hållbara sätt att motverka och behandla grödor mot bakterier. Idag är det mest vanliga tillvägagångssättet antibiotika men detta är inte hållbart p.g.a uppkomst av antibiotikaresistens. Antibiotika är inte heller tillgängligt för alla bönder och grödor då kostnaden blir för hög. Världsbefolkningen växer och om 80 år beräknas det bo mellan 9.9 och 12.7 biljoner (95% konfidens) människor på jorden. Växande befolkning samt ökande klimatförändringar, som torka och höjda temperaturer kräver nya bekämpningsmetoder mot bakterier för att tillgodose behoven i framtiden. Det saknas information om hur växter hanterar och reglerar bakteriella hot, därför är målet med denna studie att bidra med kunskap kring den transkriptionella regleringen av växters immunsystem mot bakterier. För att göra detta har promotorsekvenser hos gener som är förknippade med immunförsvaret i växter undersökts efter konserverade regulatoriska element. En känd receptor, FLS2 har en stor roll i växters försvar mot bakterier och känner igen en peptid från bakteriers flagell. Denna studie har undersökt FLS2 och den sammankopplade receptorn SERK1. Hos FLS2 kunde ingen konserverad modul hittas i uppströmsekvensen, däremot observerades ett 8 bp långt motiv, CAACTTG, i alla undersökta arter. I SERK1 hittades en lång konserverad modul bestående av flera motiv. Både FLS2-motifet och två motiv i SERK1-modulen binds av transkriptionsfaktorn MYC2. För att testa hypotesen att MYC2 bidrar till den transkriptionella regleringen av FLS2 och SERK1 har en experimentell plan utformats, där Nicotiana benthamiana transfekteras av Agrobacterium tumefaciens innehållandes promotorsekvenserna samt generna till transkriptionsfaktorn MYC2. En ökad förståelse kring de olika delarna och mekanismerna som medverkar inom växters immunförsvar kan bidra till den fortsatta forskningen mot hållbara lösningar till att säkra mat i framtiden. / Several factors contribute to the demand of new, sustainable solutions to bring food security to the world population. The United Nations predicts, with a confidence of 95%, that the world population will be between 9.9 and 12.7 billion by year 2100. At the same time plant agriculture as seen today is threatened by climate changes e.g., rising temperatures and more extreme weather conditions. In addition, plant bacterial pathogens reduce yields, and cause losses of over $1 billion dollars worldwide every year to the food production chain. The currently most used and effective treatment against bacterial infections on crops is antibiotics, but this is not a viable alternative for most growers due to increasing antibiotic resistance and the high development, production, and distribution cost. During the upcoming years development of new approaches against bacterial infections on crops is of high importance but currently there are information gaps in the field of plant defense regulation systems. This study was aimed to provide knowledge about the transcriptional regulation of genes that are included in plant immune system towards bacteria. To investigate this, conserved regulatory elements of the upstream sequences of two defense-related plant receptor kinases, FLS2 and SERK1, was searched for in different species. FLS2 is a surface receptor that recognizes a peptide derived from the bacterial flagellin protein, and is part of the pathogen-triggered immunity response of most of higher plants. In FLS2 no conserved module was found but a single motif, CAACTTG, is conserved in all chosen species. In SERK1 a strikingly long and conserved module was found. Both the FLS2 motif and two motifs in the SERK1 module are recognition motifs with MYC2, a transcription factor involved in different plant mechanisms and the regulation of phytohormones like abscisic acid and auxin. To address whether MYC2 is involved in the transcriptional regulation of FLS2, an experimental approach is described, involving transactivation by MYC2 of FLS2 reporter constructs, studies using agroinfiltration in Nicotiana benthamiana. An increased knowledge about the different components and mechanisms of plant defense regulation will help the research towards new bactericides, transgenic plants, and other ways to secure food for upcoming generations.
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