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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
31

Investigation of the interactions between the bacterial homologue to actin, and the chaperone GroEL/ES through a combination of protein engineering and spectroscopy / Undersökning av interaktionerna mellan MreB, den bakteriella homologen till aktin, och chaperonet GroEL/ES genom en kombination av protein engineering och spektroskopi

Blom, Lillemor January 2008 (has links)
<p>Molecular chaperones help many proteins in the cell reach their native conformation. The mechanism with which they do this has been studied extensively, but has not been entirely elucidated. This work is a continuation of the study done by Laila Villebeck et al. (2007) on the conformational rearrangements in the eukaryotic protein actin in interaction with the eukaryotic chaperone TRiC. In this study the intentions were to analyze the protein MreB, a prokaryotic homologue to actin, when interacting with the prokaryotic chaperone GroEL. The purpose was to investigate if the mechanisms of GroEL and TRiC are similar. The analysis of the conformation of MreB was to be made through calculations of fluorescence resonance energy transfer (FRET) between two positions in MreB labeled with fluorescein. A MreB mutant was made through site-specific mutagenesis to enable labeling at a specific position. Another single mutant and a corresponding double mutant needed for these measurements were avaliable from earlier studies. The results from fluorescence measurements on these mutants indicated that the degree of labeling was insufficient for accurate determination of FRET. Suggestions are made on improvements of the experimental approach for future studies.</p>
32

Elucidation of the product synthesis of the sesquiterpene synthase Cop6 isolated from <em>Coprinus cinereus</em>

Andersson, Marie January 2009 (has links)
<p>Mushrooms are believed to have a great potential for production of bioactive metabolites e. g. terpenes, a group of interesting compounds with diverse chemical properties such as antitumour and antibacterial activity. Cop6 is a terpene cyclase isolated from the mushroom <em>Coprinus cinereus</em> that catalyzes the cyclization of farnesyl diphosphate (FPP) to mainly α-cuprenene. In this study gas chromatography combined with mass spectroscopy (GC-MS) is used to analyze the product profile of Cop6 mutants created by PCR based site directed mutagenesis. The goal is to produce trichodiene, the parent hydrocarbon in the biosynthesis of trichothecene antibiotics and mycotoxins. Valine instead of tyrosine in amino acid position 195 resulted in cyclisation of (E)-β-Farnesene and (3Z,6E)-α-Farnesene besides the products of the wild type enzyme. Another mutant with aspartic acid instead of asparagine in position 224 resulted in the synthesis of β-Bisabolene except for α-cuprenene and methionine in position 74 instead of isoleucine killed the activity of the cyclase. Furthermore, an attempt to saturation of position 98 was made, resulting in four mutants. Two of them essentially killed the activity of the cyclase whereas two had minor effect of the product profile compared to the wild type. </p>
33

Expression and Mutagenesis studies of Candida antactica lipase B

Rotticci-Mulder, Johanna C. January 2003 (has links)
Recombinant Candida antarctica lipase B was successfullyproduced in the methylotropic yeast Pichia pastoris. Thespecific activities of Candida antarctica lipase B produced inPichia pastoris and commercial Candida antarctica lipase B fromNovozymes were the same. In shake-flask cultivations theexpression levels were about 25 mg L-1. Production levels couldbe increased to 1.5 g L-1, using a fermentor. A model tosimulate growth and oxygen consumption was described. The highcell density growth could be explained by the low maintenancecoefficient of Pichia pastoris. Enrichment of the aeration withoxygen increased the recombinant protein production. The lipasewas also produced as a fusion to a cellulose binding module.The cellulose binding module did not interfere with thespecific activity of the lipase. With this fusion proteincatalytic reactions can be performed in close proximity to acellulose surface. The binding module can also function as anaffinity tag for purification. Establishment of the Candidaantarctica lipase B production system allowed the engineeringof Candida antarctica lipase B variants. Four differentvariants were produced in order to investigate if electrostaticinteractions contributed to enantioselectivity. Theenantioselectivity of two halogenated secondary alcohols wasdoubled for the Ser47Ala variant. Thisimplied thatelectrostatic interactions are important forenantioselectivity. The Trp104His variant showed a decrease inenantioselectivity for all tested substrates. This was causedby an increase in the size of the stereoselectivity pocket.Symmetrical secondary alcohols of different size were used tomap the stereoselectivity pocket. A substituent as large as apropyl or isopropyl could be accommodated in the pocket of theTrp104His variant. In the wild-type lipase thestereoselectivity pocket was estimated to fit an ethyl group.The enzyme variants were subjected to a thermodynamic study, toelucidate changes in the enthalpic and entropic contributionsto enantioselectivity. The enthalpic and entropic contributionschanged for the different lipase variants and werecompensatory. The compensation was not perfect, allowing forchanges in enantioselectivity. In general one can conclude that rational design of newenzyme properties, in order to change the substrateselectivity, is feasible if based on a thorough model ofsubstrate enzyme interactions. <b>Key words:</b>Protein expression, Candida antarctica lipaseB, Pichia pastoris, sitedirected mutagenesis, fermentation,selectivity
34

Elucidation of the product synthesis of the sesquiterpene synthase Cop6 isolated from Coprinus cinereus

Andersson, Marie January 2009 (has links)
Mushrooms are believed to have a great potential for production of bioactive metabolites e. g. terpenes, a group of interesting compounds with diverse chemical properties such as antitumour and antibacterial activity. Cop6 is a terpene cyclase isolated from the mushroom Coprinus cinereus that catalyzes the cyclization of farnesyl diphosphate (FPP) to mainly α-cuprenene. In this study gas chromatography combined with mass spectroscopy (GC-MS) is used to analyze the product profile of Cop6 mutants created by PCR based site directed mutagenesis. The goal is to produce trichodiene, the parent hydrocarbon in the biosynthesis of trichothecene antibiotics and mycotoxins. Valine instead of tyrosine in amino acid position 195 resulted in cyclisation of (E)-β-Farnesene and (3Z,6E)-α-Farnesene besides the products of the wild type enzyme. Another mutant with aspartic acid instead of asparagine in position 224 resulted in the synthesis of β-Bisabolene except for α-cuprenene and methionine in position 74 instead of isoleucine killed the activity of the cyclase. Furthermore, an attempt to saturation of position 98 was made, resulting in four mutants. Two of them essentially killed the activity of the cyclase whereas two had minor effect of the product profile compared to the wild type.
35

Improvement Of Biohydrogen Production By Genetic Manipulations In Rhodobacter Sphaeroides O.u.001

Kars, Gokhan 01 October 2008 (has links) (PDF)
Rhodobacter sphaeroides O.U.001 is a purple non-sulphur bacterium producing hydrogen under photoheterotrophic, nitrogen limited conditions. Hydrogen is produced by Mo-nitrogenase but substantial amount of H2 is reoxidized by a membrane bound uptake hydrogenase. In this study, hydrogen production and the expression of structural nitrogenase genes were investigated by varying molybdenum and iron ion concentrations. These two elements are found in the structure of Mo-nitrogenase and they are important for functioning of the enzyme. The results showed that hydrogen production and nifD gene expression increased upon increase in molybdenum concentration. Increasing iron concentration had also positive effect on hydrogen production and nifK gene expression. To improve the hydrogen producing capacity of R. sphaeroides O.U.001, hupSL genes encoding uptake hydrogenase were disrupted in two different methods. In the first method, hup genes were disrupted by gentamicin resistance gene insertion. In the second method, part of the hup gene was deleted without using antibiotic resistance gene. The wild type and the hup- mutant cells showed similar growth patterns but substantially more hydrogen was produced by the mutant cells. The genes coding for hox1 hydrogenase of Thiocapsa roseopersicina was aimed to be expressed in R. sphaeroides O.U.001 to produce H2 under nitrogenase repressed and mixotrophic conditions. The hox1 hydrogenase genes of T. roseopersicina were cloned and transferred to R. sphaeroides. Although the cloning was successful, the expression of hydrogenase was not achieved by using either the native promoter of hox1 hydrogenase or the crtD promoter of T. roseopersicina.
36

Deletion Mutation Of Glnb And Glnk Genes In Rhodobacter Capsulatus To Enhance Biohydrogen Production

Pekgoz, Gulsah 01 September 2010 (has links) (PDF)
Rhodobacter capsulatus is a photosynthetic, purple non-sulfur (PNS) bacterium that produces biohydrogen via photofermentation. Nitrogenase enzyme is responsible for hydrogen production / during fixation of molecular nitrogen into ammonium, hydrogen is produced. Since this process is an energetically expensive process for the cell, hydrogen production is strictly controlled at different levels. When ammonium is present in the environment, hydrogen production completely ceases. The key proteins in the regulation of nitrogenase by ammonium are two PII proteins / GlnB and GlnK. &lsquo / Hyvolution&rsquo / , 6th framework EU project, aims to achieve maximum hydrogen production by combining two hydrogen production processes / dark fermentation and photofermentation. In the first stage of the overall process, biomass is used for hydrogen production in dark fermentation process. Then, the effluent of dark fermentation is further utilized by photosynthetic bacteria to produce more hydrogen. However, the effluent of dark fermentation contains high amount of ammonium, which inhibits photofermentative hydrogen production. In order to achieve maximum hydrogen production, ammonium regulation of nitrogenase enzyme in R.capsulatus has to be released. For this purpose, all PII signal transduction proteins of R.capsulatus (GlnB and GlnK) were targeted to be inactivated by site-directed mutagenesis. The internal parts of glnB and glnK genes were deleted individually without using antibiotic cassette insertion. The successful glnB mutant was obtained at the end of mutagenesis studies. In the case of glnK mutation, the suicide vector was constructed and delivered into the cells. However, glnK mutant could not be obtained. The effect of ammonium on glnB mutant R.capsulatus was investigated and compared with wild type. Biomass of the bacterial cultures, pH of the medium and amount of produced hydrogen were periodically determined. Moreover, the concentrations of acetic, lactic, formic and propionic acids in the medium were periodically measured. Both wild type and glnB mutant grew on acetate and effectively utilized acetate. Ammonium negatively affected hydrogen production of glnB mutant and wild type. The ammonium inhibition of hydrogen production did not release in glnB mutant due to the presence of active GlnK protein in the cell / hence, inactivation of one of PII proteins was not enough to disrupt ammonium regulation of the cell. Moreover, kinetic analysis of bacterial growth and hydrogen production were done. Growth data fitted to the Logistic Model and hydrogen production data fitted to the Modified Gompertz Model.
37

Expression and Mutagenesis studies of Candida antactica lipase B

Rotticci-Mulder, Johanna C. January 2003 (has links)
<p>Recombinant Candida antarctica lipase B was successfullyproduced in the methylotropic yeast Pichia pastoris. Thespecific activities of Candida antarctica lipase B produced inPichia pastoris and commercial Candida antarctica lipase B fromNovozymes were the same. In shake-flask cultivations theexpression levels were about 25 mg L-1. Production levels couldbe increased to 1.5 g L-1, using a fermentor. A model tosimulate growth and oxygen consumption was described. The highcell density growth could be explained by the low maintenancecoefficient of Pichia pastoris. Enrichment of the aeration withoxygen increased the recombinant protein production. The lipasewas also produced as a fusion to a cellulose binding module.The cellulose binding module did not interfere with thespecific activity of the lipase. With this fusion proteincatalytic reactions can be performed in close proximity to acellulose surface. The binding module can also function as anaffinity tag for purification. Establishment of the Candidaantarctica lipase B production system allowed the engineeringof Candida antarctica lipase B variants. Four differentvariants were produced in order to investigate if electrostaticinteractions contributed to enantioselectivity. Theenantioselectivity of two halogenated secondary alcohols wasdoubled for the Ser47Ala variant. Thisimplied thatelectrostatic interactions are important forenantioselectivity. The Trp104His variant showed a decrease inenantioselectivity for all tested substrates. This was causedby an increase in the size of the stereoselectivity pocket.Symmetrical secondary alcohols of different size were used tomap the stereoselectivity pocket. A substituent as large as apropyl or isopropyl could be accommodated in the pocket of theTrp104His variant. In the wild-type lipase thestereoselectivity pocket was estimated to fit an ethyl group.The enzyme variants were subjected to a thermodynamic study, toelucidate changes in the enthalpic and entropic contributionsto enantioselectivity. The enthalpic and entropic contributionschanged for the different lipase variants and werecompensatory. The compensation was not perfect, allowing forchanges in enantioselectivity.</p><p>In general one can conclude that rational design of newenzyme properties, in order to change the substrateselectivity, is feasible if based on a thorough model ofsubstrate enzyme interactions.</p><p><b>Key words:</b>Protein expression, Candida antarctica lipaseB, Pichia pastoris, sitedirected mutagenesis, fermentation,selectivity</p>
38

The structural basis for the catalytic specificity of manganese lipoxygenases : 3D structure analysis of the lipoxygenase of Magnaporthe oryzae

Wennman, Anneli January 2015 (has links)
Lipoxygenases (LOX) catalyze regio- and stereospecific oxygenation of polyunsaturated fatty acids to hydroperoxides. These hydroperoxides are further metabolized to leukotrienes and lipoxins in mammals, and are involved in asthma and inflammation. LOX of animals and plants contain iron as catalytic metal (FeLOX). Filamentous fungi use both FeLOX, and manganese containing LOX (MnLOX). The role of LOX in fungi is still not known. This thesis focuses on expression of novel MnLOX, analyses of their reaction mechanism and products by HPLC-MS/MS, protein crystallization and analysis of the first MnLOX structure.   MnLOX from G. graminis, M. salvinii, M. oryzae, F. oxysporum and C. gloeosporioides were expressed in Pichia pastoris, purified and characterized by HPLC-MS/MS. All MnLOX catalyzes suprafacial hydrogen abstraction and oxygen insertion. Replacement of one Ile to Phe in the active site of MnLOX of G. graminis could switch the mechanism from suprafacial to mainly antarafacial. MnLOX of F. oxysporum was interesting since it catalyzes oxygenation of linoleic acid to 11R- instead of the more common 11S-hydroperoxides. This feature could be attributed to a single Ser/Phe exchange in the active site.   We found that Gg-MnLOX utilizes hydrogen tunneling in the reaction mechanism, but was slightly more temperature dependent than soybean FeLOX. It is an intriguing question why some fungal LOX use manganese and not iron as catalytic metal and whether the large redox potential of Mn2+/Mn3+ (1.5 V) can be tuned close to that of Fe2+/Fe3+ (0.77 V) for redox cycling and catalysis. We present crystallization conditions for two MnLOX, and the 2.07 Å crystal structure of MnLOX from M. oryzae, solved using sulfur and manganese single anomalous dispersion (SAD). The structure reveals a similar metal coordinating sphere as FeLOX but the metal ligand Asn473 was positioned on a short loop instead of a helix and formed interactions with a conserved Gln. This feature could be essential for the use of manganese as catalytic metal in LOX. We found three Phe residues that likely facilitate the suprafacial hydrogen abstraction and oxygen insertion for MnLOX. These findings provide new insight into the unique reaction mechanism of MnLOX.
39

Functional mapping and in vivo metabolism of the monoclonal antibody TS1 and its single-chain fragment : Its interaction with the antigen and the anti-idiotype

Holm, Patrik January 2006 (has links)
Antibodies are proteins capable of specific interactions to a wide range of molecules. These interactions are facilitated by the complementary determining regions (CDR). Carcinomas are the most common of human cancers and they release significant amount of cytokeratins (CK) in the necrotic areas of the tumors. The CKs stay in the tumor, since they have low solubility. The antibody studied in this thesis, the anti-CK 8 antibody TS1, has shown to be effective in tumor targeting and is proposed to be useful in therapy. Single-chain antibodies (scFv) are recombinant antibodies which are much smaller than the intact IgG. This is an advantage when used in tumor therapy, since they can penetrate the tumors more easily than the larger IgG. Moreover, they are expressed by one single gene which make them easy to modify, for example by site-directed mutagenesis. The anti-idiotypic antibody αTS1 can be used to clear the TS1 form the circulation and thereby clear the body from non-tumor bound TS1 in therapy. To be able to modify the binding of an antibody to its antigen and or anti-idiotype, these interactions must be studied. In this study this is accomplished by chemical modifications of the IgGs TS1 and αTS1 and the antigen CK 8. Guided by these results, amino acid residues were mutated by using site-directed mutagenesis in the TS1-218 scFv and the effects were studied. From mutational study results, the functional epitope could be mapped and it was found that there are mainly tyrosines, but also charged residues, serine and a tryptophan that are important for both interactions. The binding of TS1-218 to both αTS1 and CK 8 could be improved by changing the negatively charged side-chains by mutations to their corresponding amide or alanine. Both the IgG and scFv versions of TS1 were administered in vivo. The IgG αTS1 was used to clear the TS1 from the circulation by forming immune complexes. The immune complexes, consisting of four or more antibodies, were mainly metabolized by the liver. The scFv TS1-218 could localize to the tumor in a tumor xenograft mouse model, although a higher uptake would be desired in a therapeutic strategy. The scFv was cleared rapidly by the kidneys, but the clearance could be slowed by pre-formed immune complexes with anti-TS1 scFv in vitro, prior to administration in vivo.
40

HOW A SILENT MUTATION SUPPRESSES THE ACTIVITY AND IRON INCORPORATION IN SUPEROXIDE DISMUTASE

Mei, Xiaonan 01 January 2012 (has links)
A mutation (CTG to TTG) of FeSOD gene was found in Escherichia coli. Since they both encode leucine, it is a silent mutation. Site-­‐directed mutagenesis was applied to correct the mutation, and the mutant FeSOD (before gene correction) and wild type FeSOD (after gene correction) were purified. The FeSODs from the two genes were Characterized using different assays and spectroscopic methods including EPR and CD. The requirement for the rare codon TTG may result in slowed translation and heavy demand on a scarce tRNA. Cultures expressing wild type FeSOD are better able to grow for long times after addition of IPTG and more mature to incorporate Fe atoms to the active sites than are cultures expressing the mutant gene. Moreover, the wild type FeSOD has more activity than the mutant. To our knowledge, this is the first time that a silent mutation has been demonstrated to affect metal incorporation into a metalloenzyme.

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