Browsing by Subject "purification"
Now showing items 1-6 of 6
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(2023)In recent years, exceptionally large bacteriophages with genome sizes over 500 kilobase pairs (kbp), called megaphages, have been discovered from sequence data, but no previous publications discussing megaphage isolates have been published. In 2011, a phage infecting a Flavobacterium strain was isolated from the Kymijoki river. The phage, named FKy-1, was determined to have a genome size of 643 kbp, based on yet unpublished results, making it the first described megaphage isolate. In this study, we focused on characterizing megaphage FKy-1, by observing the virus morphology, determining the type and length of its life cycle, and measuring its stability in different temperatures and conditions. Purification of the phage by precipitation and ultracentrifugation in a sucrose density gradient resulted in separation of both virion and phage subcomplexes. Based on transmission electron microscopy and cryogenic electron microscopy, FKy-1 was observed to have typical myovirus morphology, with a large icosahedral head of around 160 nm in diameter, and a tail of around 180 nm in length. Molecular masses of the major proteins present in the virion and phage subcomplexes were estimated using sodium dodecyl sulfate polyacrylamide gel electrophoresis to be 50-70 kDa for the major capsid protein, 60-70 kDa and 150-200 kDa for the major tail proteins. Digestion attempts with restriction endonucleases proved unsuccessful, indicating possible phage genome modifications or other defensive mechanisms. The phage was determined to have a lytic life cycle which takes over 3 h to cause cell lysis, resulting in the release of around 10 progenies per infected host cell. The phage proved to be quite stable, with minimal impact on infectivity measured at a temperature range of -20 °C to +40 °C, and in minimal buffer conditions. In summary, we proved that the purification method used here is well suited for megaphages, and that FKy-1 is of myovirus morphology, produces a low number of progenies per host, and is relatively stable. As no other publications regarding megaphages exist, this study acts as a good basis for future research regarding megaphage morphology, infection cycle and stability.
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(2023)In recent years, exceptionally large bacteriophages with genome sizes over 500 kilobase pairs (kbp), called megaphages, have been discovered from sequence data, but no previous publications discussing megaphage isolates have been published. In 2011, a phage infecting a Flavobacterium strain was isolated from the Kymijoki river. The phage, named FKy-1, was determined to have a genome size of 643 kbp, based on yet unpublished results, making it the first described megaphage isolate. In this study, we focused on characterizing megaphage FKy-1, by observing the virus morphology, determining the type and length of its life cycle, and measuring its stability in different temperatures and conditions. Purification of the phage by precipitation and ultracentrifugation in a sucrose density gradient resulted in separation of both virion and phage subcomplexes. Based on transmission electron microscopy and cryogenic electron microscopy, FKy-1 was observed to have typical myovirus morphology, with a large icosahedral head of around 160 nm in diameter, and a tail of around 180 nm in length. Molecular masses of the major proteins present in the virion and phage subcomplexes were estimated using sodium dodecyl sulfate polyacrylamide gel electrophoresis to be 50-70 kDa for the major capsid protein, 60-70 kDa and 150-200 kDa for the major tail proteins. Digestion attempts with restriction endonucleases proved unsuccessful, indicating possible phage genome modifications or other defensive mechanisms. The phage was determined to have a lytic life cycle which takes over 3 h to cause cell lysis, resulting in the release of around 10 progenies per infected host cell. The phage proved to be quite stable, with minimal impact on infectivity measured at a temperature range of -20 °C to +40 °C, and in minimal buffer conditions. In summary, we proved that the purification method used here is well suited for megaphages, and that FKy-1 is of myovirus morphology, produces a low number of progenies per host, and is relatively stable. As no other publications regarding megaphages exist, this study acts as a good basis for future research regarding megaphage morphology, infection cycle and stability.
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(2021)The endoplasmic reticulum (ER) is an important organelle of the cell where a high number of proteins are synthesized and modified to obtain their final structure. Therefore, the ER stress, which is caused by accumulation of unfolded proteins in the ER, is not to be taken lightly since it could contribute to many diseases, such as cancer and neurodegenerative diseases. The response to the ER stress is the unfolded protein response (UPR), which is an adaptive system that helps in adjusting for increased folding needs within the ER. One of the main protein branches in the UPR is inositol requiring enzyme 1 (IRE1). IRE1 detects the status of protein folding inside the ER and initiates the UPR signaling pathway to achieve either normal folding status or cell death. The aim of this research was to express yeast IRE1 in E.coli and human IRE1 in insect cells, purify with affinity chromatography and study the IRE1’s crystal structure with a small molecule modulator that could possibly enhance its activity. The protein was expressed successfully and purified with glutathione S-transferase (GST) tag, and the activity of the pure protein was determined. The structural studies were not fully completed since the absolute purity and yield that was necessary for crystallization was not achieved due to loss of protein during gel filtration and precipitation. Based on the results it is likely that the structure of the protein could be solved and further biochemical and structural studies with F10 are possible.
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(2021)The endoplasmic reticulum (ER) is an important organelle of the cell where a high number of proteins are synthesized and modified to obtain their final structure. Therefore, the ER stress, which is caused by accumulation of unfolded proteins in the ER, is not to be taken lightly since it could contribute to many diseases, such as cancer and neurodegenerative diseases. The response to the ER stress is the unfolded protein response (UPR), which is an adaptive system that helps in adjusting for increased folding needs within the ER. One of the main protein branches in the UPR is inositol requiring enzyme 1 (IRE1). IRE1 detects the status of protein folding inside the ER and initiates the UPR signaling pathway to achieve either normal folding status or cell death. The aim of this research was to express yeast IRE1 in E.coli and human IRE1 in insect cells, purify with affinity chromatography and study the IRE1’s crystal structure with a small molecule modulator that could possibly enhance its activity. The protein was expressed successfully and purified with glutathione S-transferase (GST) tag, and the activity of the pure protein was determined. The structural studies were not fully completed since the absolute purity and yield that was necessary for crystallization was not achieved due to loss of protein during gel filtration and precipitation. Based on the results it is likely that the structure of the protein could be solved and further biochemical and structural studies with F10 are possible.
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(2017)Alphaviruses are single-stranded positive-sense RNA viruses that have been the cause of numerous epidemics in the past decades. The viral genome codes four nonstructural proteins that are associated with viral RNA replication. The translation product is a polyprotein from which the individual nonstructural proteins are cleaved. The genome is transcribed by the nonstructural proteins to produce a negative strand, which acts as a template in the synthesis of positive strands. The subgenomic RNA, which codes the structural proteins, is transcribed from the negative template strand. The replication of genomic and subgenomic RNA strands is associated with replication complexes composed of the nonstructural proteins. The replication complexes are housed in membrane invaginations called spherules on the plasma membrane and endolysosomal vesicles. Transfection of plasmids expressing viral replicase proteins and template RNA can also induce formation of replication complexes in addition to live virus infection. Purification of the replication complexes is necessary for detailed functional and structural analysis. In this work, two methods were used in the purification of replication complexes. In the first method, mammalian cells were infected with viruses and replication complexes were blocked on the plasma membrane by drug treatment to prevent transport to endolysosomal vesicles. Cells were lysed and nuclei were removed by centrifugation. The postnuclear supernatant was sedimented by ultracentrifugation in a discontinuous gradient. The gradient was fractionated and the fraction containing the replication complexes was subjected to equilibrium ultracentrifugation to separate particles by density. The fraction containing the replication complexes was studied using electron microscope, and protein and lipid analysis. In the second method, mammalian cells were transfected with plasmids expressing a template RNA and the viral polyprotein to induce formation of replication complexes. A sequence coding hemagglutinin peptide had been inserted into the polyprotein sequence coding for the nonstructural protein with polymerase activity. Cells were lysed and nuclei were removed. Rreplication complexes were immunocaptured using the hemagglutinin tag by subjecting the supernatant to anti-HA agarose beads. Captured replication complexes were eluted with Laemmli sample buffer and purification was examined using Western blotting. Spherules associated with replication complexes were observed using electron microscope and the presence of nonstructural proteins was confirmed with antibodies. Spherules were observed in low numbers and Western blotting revealed that samples contained cellular contaminants. Purification of replication complexes using immunocapture was very low, but more than that of untagged samples. Although significant purification of replication complexes was not achieved, progress was made in the optimization of the methods.
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Valittujen makrolidien ominaisuudet ja niiden vaikutukset fermentoinnin jälkeiseen jatkokäsittelyyn (2010)The characteristics of macrolides are discussed in general level in the theoretical part of this Master's thesis. The discussion is focused on the properties of two macrolides in molecular level and their tendency to form tautomeric forms highlighting the structural similarities and differences of these macrolides, which will affect both the mechanisms of action and the metabolism. Attention is also paid to biosynthesis and manufacturing process keeping focus on downstream process, especially the impurities, which arise from the macrolide biosynthesis. Also the principles of argentation chromatography are discussed. In the experimental part of Master's thesis a purification method for one macrolide was developed using argentation chromatography. Conventional chromatographic purifications cannot separate the macrolide from its impurities. The purity of the macrolide after argentation chromatography was 98.6%. Also a new crystallization method was developed, which produces anhydrous form of the macrolide instead of traditional monohydrate form. A method for analysing the macrolide using HPLC was developed. The method was validated according to ICH guidelines. The tautomeric forms and the impurities of the macrolide were analysed using LC/MS. One of these impurities was isolated and analysed with NMR thus confirming its identity. An analysed NMR spectrum of this impurity has not been published according to our best knowledge. A previously unknown impurity was identified based on MS analysis and retention time.
Now showing items 1-6 of 6