Global ETD Search

1	THE EFFECT OF NACL ON AKINETE DIFFERENTIATION IN THE CYANOBACTERIUM NOSTOC PUNCTIFORME Heekin, Jonathan 28 April 2008 (has links) Nostoc punctiforme is a nitrogen-fixing, symbiotic/free-living cyanobacterium. There has been a great deal of research conducted on the genomic nature of N. punctiforme as it pertains to its ecologically important role in the nitrogen cycle in varied environments around the world. My study concentrated on the dormant cell type known as the akinete. Increasing concentrations of NaCl were used to follow the growth phases from germination to akinete formation (lag phase-logarithmic growth phase-stationary phase). I found that increased salt concentrations caused N. punctiforme to form akinetes faster when compared to the control. Germination rates were not greatly increased or shortened by salt concentrations at or below 40 mM NaCl. Damage to cells due to NaCl was observed between 105 mM and 500 mM. Physiological studies, such as this one, enable better quantifiable field research since the organism’s limitations under laboratory conditions are known. This research allows researcher to more accurately plan and pick study sites, develop field studies and gives a solid basis for comparison to the natural environment. Nostoc punctiforme Biology Life Sciences
2	The Heterocysts of Nostoc punctiforme : From Proteomics to Energy Transfer Cardona, Tanai January 2009 (has links) The aim of this thesis is to provide a thorough characterization of the photosynthetic machinery from the heterocysts of Nostoc punctiforme strain ATCC 29133. In this thesis I describe the protocols I have optimized for the isolation of thylakoids from vegetative cells, the purification of heterocysts and the isolation of thylakoids from the purified heterocysts. The composition of the thylakoid membranes was studied by two dimensional electrophoresis and mass-spectrometry. Further insight into the functionality of the photosynthetic complexes was obtained by EPR, electron transport measurements through Photosystem II (PSII), and fluorescence spectroscopy. The proteome of the heterocysts thylakoids compared to that of the vegetative cell was found to be dominated by Photosystem I (PSI) and ATP-synthase complexes, both essential for keeping high nitrogenase activities. Surprisingly, we found a significant amount of assembled monomeric PSII complexes in the heterocysts thylakoid membranes. We measured in vitro light-driven electron transfer from PSII in heterocysts using an artificial electron donor, suggesting that under certain circumstances heterocysts might activate PSII. Parallel to my main research I also worked in a collaboration to elucidate the total proteome of Nostoc sp. strain 7120 and Nostoc punctiforme using quantitative shotgun proteomics. Several hundred proteins were quantified for both species. It was possible to trace the detailed changes that occurred in the energy and nitrogen metabolism of a heterocyst after differentiation. Moreover, the presence of PSII proteins identified in our membrane proteome was also confirmed and extended. Lastly, I studied how the heterocysts are capable of responding to variations in light quality as compared to vegetative cells. Using 77 K fluorescence spectroscopy on heterocysts and vegetative cells previously illuminated with light at specific wavelengths, I was able to demonstrate that heterocysts still possess a possibly modified but functional antenna system, capable of harvesting light and transferring energy preferentially to PSI. The characterization of the membrane and total proteome permitted to draw a more comprehensive and integrated picture of the interplay between the distinct metabolic processes that are carried out in each cell type at the same time; from oxygenic photosynthesis and carbon fixation in the vegetative cells to the anoxygenic cyclic photophosphorylation essential to power nitrogen assimilation in the heterocysts. Nostoc punctiforme heterocyst photosynthesis thylakoid isolation proteomics photosystem energy transfer hydrogen Biochemistry Biokemi
3	Evidence that a partner-switching regulatory system modulates hormogonium motility in the filamentous cyanobacterium Nostoc punctiforme Riley, Kelsey Wynne 01 January 2018 (has links) Partner-switching regulatory systems (PSRSs) are utilized by many different bacteria to regulate a wide array of cellular responses, from stress response to expression of virulence factors. The filamentous cyanobacterium Nostoc punctiforme can transiently differentiate motile filaments, called hormogonia, in response to various changes in the environment. Hormogonia utilize a Type IV pilus (T4P) complex in conjunction with a secreted polysaccharide for gliding motility along solid surfaces. This study identified three genes, designated hmpU, hmpW, and hmpV, encoding the protein components of a PSRS involved in regulation of hormogonium motility in N. punctiforme. Although mutant strains with in-frame deletions in hmpU, hmpW, and hmpV differentiated morphologically distinct hormogonium-like filaments, further phenotypic analysis demonstrated significant distinctions among the strains. The ∆hmpW strain contained a higher percentage of motile filaments that moved faster than the wild-type strain, while the ∆hmpU and ∆hmpV strains consisted of fewer motile filaments that moved at a slower rate compared to wild type. Immunoblotting and immunofluorescence of PilA, the major component of the pilus in the T4P system, showed that although all mutant strains appeared to express similar levels of PilA protein, the ∆hmpU and ∆hmpV strains displayed reduced extracellular PilA. Lectin blotting and staining with fluorescently-labeled UEA lectin demonstrated a decrease in extracellular hormogonium polysaccharide in the ∆hmpU and ∆hmpV strains, consistent with the current understanding that the polysaccharide is secreted via the T4P system. Epistasis analysis demonstrated that the ∆hmpW, ∆hmpV double-deletion mutant strain displayed reduced spreading in plate motility assays, similar to the ∆hmpV single mutant. Together, these results support a model in which the HmpU phosphatase and HmpW serine kinase control the phosphorylation state of the HmpV protein, modulating its activity on a downstream target to ultimately promote activation of the T4P motor complex and enhance hormogonium motility. cyanobacteria gliding motility hormogonia hormogonium Nostoc punctiforme partner-switching biology Biology
4	Evolution modularer Multienzymsysteme des bakteriellen Sekundärstoffwechsels Jenke-Kodama, Holger Michael 29 October 2007 (has links) Modulare Polyketidsynthasen (PKS) sind Multienzymsysteme des bakteriellen Sekundärstoffwechsels. An ihnen läuft eine schrittweise Biosynthese vielfältiger Kohlenstoff-Gerüste ab, die von einfachen Carbonsäure-Einheiten ausgeht. Polyketid-Verbindungen zeigen eine große Bandbreite pharmazeutisch interessanter Aktivitäten. In dieser Arbeit wurde eine Reihe von Evolutionsstudien durchgeführt. Zunächst wurden die phylogenetischen Beziehungen zwischen modularen PKS und anderen PKS-Systemen sowie Fettsäuresynthasen untersucht, wodurch ihre zentrale Stellung innerhalb eines langen Evolutionsprozesses gezeigt werden konnte. Eine detaillierte Analyse der Phylogenien von Domänen bakterieller modularer PKS ergab, dass das Ausmaß an Genduplikationen, Genverlusten und Ereignissen horizontalen Gentransfers zwischen den verschiedenen Bakteriengruppen beträchtlich variiert. Aus der Genomsequenz des Actinobakteriums Streptomyces avermitilis wurden die Phylogenien aller Domänentypen rekonstruiert. Der Vergleich dieser Einzelphylogenien ermöglichte es, eine Reihe von homologen Rekombinationsereignissen aufzufinden. Homologe Rekombination scheint der Hauptmechanismus zu sein, auf dem die Strukturvielfalt der Polyketide in Bakterien beruht. Mit Hilfe eines „genome mining“-Ansatzes konnte im Genom des Cyanobakteriums Nostoc punctiforme eine Reihe von Biosynthese-Clustern, die zu den PKS und nichtribosomalen Peptidsynthetasen gehören, identifiziert werden. Durch chromatographische und massenspektrometrische Analysen von Zellextrakten und Kulturüberständen konnten einige der Biosynthese-Cluster bestimmten Metaboliten zugeordnet werden. Eines der Cluster wurde hinsichtlich des produzierten Metaboliten und der Regulationsstruktur eingehender charakterisiert. Die Folgerungen aus den gewonnen Ergebnissen werden im allgemeinen Zusammenhang der Evolution metabolischer Diversität ausführlich diskutiert. / Modular polyketide synthases (PKS) are multienzym systems of bacterial secondary metabolism. They perform a stepwise biosynthesis of diverse carbon skeletons from simple carboxylic acid units. Polyketide compounds possess a wide range of pharmaceutically interesting activities. In this study, a series of evolutionary analyses was performed. Initially, the phylogenetic relationships between modular PKS and other PKS systems as well as fatty acid synthases were investigated revealing their central position within a long evolutionary process. In detail reconstruction of the phylogenies of bacterial modular PKS domains demonstrated that the extent of gene duplications, gene losses and horizontal gene transfer events varies considerably between different bacterial groups. Using the genome sequence of the actinobacterium Streptomyces avermitilis the phylogenies of all domain types were reconstructed. Comparison of these phylogenies allowed for detecting numerous events of homologous recombination, which appears to be the main mechanism underlying polyketide structural diversity in bacteria. A genome mining approach revealed a number of biosynthesis clusters of the PKS and nonribosomal peptide synthetase type in the genome of the cyanobacterium Nostoc punctiforme. Cell extracts and culture supernatants were analysed by means of liquid chromatography and mass spectrometry and some of the biosynthesis clusters could be assigned to specific metabolites. One of the clusters was characterised in greater detail regarding the produced metabolite and the cluster’s regulatory structure. The implications of the results are extensively discussed within the general context of the evolution of metabolic diversity. Evolution Polyketidsynthase Fettsäuresynthase nichtribosomale Peptidsynthetase Sekundärstoffwechsel Nostoc punctiforme Streptomyces avermitilis evolution polyketide synthase fatty acid synthase nonribosomal peptide synthetase secondary metabolism Nostoc punctiforme Streptomyces avermitilis 570 Biowissenschaften, Biologie 32 Biologie WH 4400 WX 3100 ddc:570
5	Maturation and Regulation of Cyanobacterial Hydrogenases Agervald, Åsa January 2009 (has links) Accelerated global warming plus an increasing need for energy is an equation not easily solved, thus new forms of sustainable energy production are urgently requested. In this context hydrogen production based on a cyanobacterial system offers an environmentally friendly alternative for energy capture and conversion. Cyanobacteria can produce hydrogen gas from sun light and water through the combination of photosystems and hydrogenases, and are suitable to cultivate in large scale. In the present thesis the maturation process of [NiFe]-hydrogenases is investigated with special focus on transcription of the accessory genes encoding proteins needed for assembly of the large and possibly also for the small hydrogenase subunit. The cyanobacteria used are two N2-fixing, filamentous, heterocystous strains; Nostoc sp. strain PCC 7120 and Nostoc punctiforme PCC 73102. For a biotechnological exploration of hydrogen production tools for regulatory purposes are important. The transcription factor CalA (cyanobacterial AbrB like) (Alr0946 in the genome) in Nostoc sp. strain PCC 7120 was found to be involved in hydrogen metabolism by regulating the transcription of the maturation protein HypC. Further the bidirectional hydrogenase activity was down-regulated in the presence of elevated levels of CalA, a result important to take into account when optimizing cyanobacteria for hydrogen production. CalA regulates at least 25 proteins in Nostoc sp. strain PCC 7120 and one of the down-regulated proteins was superoxide dismutase, FeSOD. The characterization of FeSOD shows that it has a specific and important function in the oxidative stress tolerance of Nostoc sp. stain PCC 7120. Since CalA is involved in regulation of both the hydrogen metabolism as well as stress responses these findings indicate that Alr0946 is an important transcription factor in Nostoc sp. strain PCC 7120 active on a global level in the cell. This thesis adds more knowledge concerning maturation and regulation of cyanobacterial hydrogenases which might be useful for future large scale hydrogen. Biohydrogen Cyanobacteria Nostoc sp. PCC 7120 Nostoc punctiforme PCC 73102 Hydrogenase Maturation Transcriptional regulation CyAbrB CalA FeSOD
6	The Cyanobacterial Uptake Hydrogenase : Regulation, Maturation and Function Holmqvist, Marie January 2010 (has links) With accellerating global warming and pollution problems a change of energy regime is necessary. Solar energy offers a clean and unlimited energy source of enormous potential. Due to it’s intermittenet nature solar energy must be stored - ideally in the chemical bond of a carrier molecule. Hydrogen gas, H2, an energy carrier with water as only emission when used in a fuel cell, is considered to be the choise for the future. In this context cyanobacteria show promising potential as future H2 factories since they can produce H2 from solar energy and water. The main enzymes directly involved in cyanobacterial hydrogen metabolism are nitrogenases and hydrogenases. Cyanobacterial hydrogenases are either uptake hydrogenases or bidirectional hydrogenases and their maturation requires assistance of six maturation proteins and two hydrogenase specific proteases. In this thesis the transcriptional regulation, maturation and function of the cyanobacterial uptake hydrogenases were investigated in the filamentous, heterocyst forming strains Nostoc punctiforme ATCC 29133 and Nostoc sp. strain PCC 7120. Five genes, encoding proteins putatively involved in the maturation of the uptake hydrogenase were identified upstream the known maturation genes. Two transcription factors, CalA and CalB, were found interacting with the stretch of DNA forming the upstream regions of the uptake hydrogenase structural genes and the novel maturation genes. The expression of the uptake hydrogenase were heterocysts specific and the specificity mapped to a short promoter region starting -57 bp upstream the transcription start point. In addition, the function of the uptake hydrogenase was inserted in a metabolic context. Among the proteases, a conserved region was discovered possibly involved in determining the hydrogenase specificity. This thesis has given valuable information about the transcriptional regulation, maturation and function of the uptake hydrogenase in filamentous, heterocystous cyanobacteria and identified new targets for bioengineering of mutant strains with higher H2 production rates. Biohydrogen CalA Cyanobacteria Hydrogenase Maturation Nostoc punctiforme ATCC 29133 Nostoc sp. PCC 7120 Transcriptional regulation Molecular biology Molekylärbiologi Molecular biology Molekylärbiologi
7	Creating an Efficient Biopharmaceutical Factory: Protein Expression and Purification Using a Self-Cleaving Split Intein Cooper, Merideth A. 07 September 2018 (has links) No description available. Chemical Engineering
8	Development of a Novel Intein-Mediated Affinity Capture Platform for Production of Recombinant Proteins and Biopharmaceuticals Taris, Joseph Edward January 2021 (has links) No description available. Chemical Engineering Molecular Biology Pharmaceuticals Biochemistry Biopharmaceuticals Bioprocessing Bioseparations Downstream Process Development Chromatography Affinity Chromatography Inteins Split Inteins Affinity Tag Removal Protein Purification Protein Engineering Nostoc Punctiforme (Npu) DnaE

Search results