Global ETD Search

1	DC1, a podoviridae with a putative cepacian depolymerase enzyme Routier, Sarah Unknown Date No description available. Burkholderia cepacia Phage Depolymerase
2	DC1, a podoviridae with a putative cepacian depolymerase enzyme Routier, Sarah 11 1900 (has links) Plaques formed by DC1 on B. cepacia LMG 18821 and B. cenocepacia PC184 are surrounded by large and expanding halos when production of the exopolysaccharide (EPS) cepacian is induced. This plaque morphology indicates that DC1 putatively carries an EPS depolymerase enzyme. Plaque halos were absent when DC1 infected a PC184 cepacian knockout mutant and a non-mucoid LMG 18821 mutant, constructed using plasposon mutagenesis. The virulence of these mutants compared to wildtype PC184 and LMG 18821 was determined using the Galleria mellonella infection model. No major changes to virulence were observed for the LMG 18821 mutant. But, the PC184 cepacian knockout mutant was attenuated for virulence suggesting that this carbohydrate pathway may play a role in pathogenesis. The gene(s) involved in halo formation remain unknown although attempts were made to determine the gene(s) involved by cloning and expressing DC1 fragments in E. coli and assaying for EPS degradation. / Microbiology and Biotechnology Burkholderia cepacia Phage Depolymerase
3	Neuartige Poly(3-Hydroxybutyrat)-Depolymerasen aus Paucimonas lemoignei und Rhodospirillum rubrum Handrick, René Unknown Date (has links) (PDF) Universiẗat, Diss., 2003--Stuttgart.
4	Regulation of Microtubule Dynamics by Molecular Motors Su, Xiaolei January 2012 (has links) Kinesin superfamily motors have a well-characterized ability to move along microtubules and transport cargo. However, some members of the kinesin superfamily can also remodel microtubule networks by controlling tubulin polymerization dynamics and by organizing microtubule structures. The kinesin-8 family of motors play a central role in cellular microtubule length control and in the regulation of spindle size. These motors move in a highly processive manner along the microtubule lattice towards plus ends. Once at the microtubule plus end, these motors have complex effects on polymerization dynamics: kinesin-8s can either destabilize or stabilize microtubules, depending upon the context. My thesis work identified a tethering mechanism that facilitates the processivity and plus end-binding activity of Kip3 (kinesin-8 in budding yeast), which is essential for the destabilizing activity of kinesin-8 in cells. A concentration-dependent model was proposed to explain the divergent effects of Kip3 on microtubule dynamics. Moreover, a novel activity of Kip3 in organizing microtubules was discovered: Kip3 can slide anti-parallel microtubules apart. The sliding activity of Kip3 counteracts the depolymerizing activity of Kip3 in controlling spindle length and stability. A lack of sliding activity causes fragile spindles during the process of chromosome segregation in anaphase. The tail domain of Kip3, which binds both microtubules and tubulin dimers, plays a critical role in all these activities. Together, my work defined multiple mechanisms by which Kip3 remodels the microtubule cytoskeleton. The physiological importance of these regulatory mechanisms will be discussed. kinesin-8 Kip3 microtubule depolymerase microtubule dynamics spindle size spindle stability cellular biology biophysics biochemistry
5	Avaliação do sistema de mobilização de poli-3-hidroxibutirato em Burkholderia sacchari. / Evaluation of poly-3-hydroxybutyrate (P3HB) mobilization system in Burkholderia sacchari. Castellanos, Nuri Andrea Merchan 19 October 2010 (has links) O sistema de mobilização intracelular de poli-3-hidroxibutirato (P3HB) em Burkholderia sacchari foi analisado. A busca em genomas de Burkholderia spp. identificou duas oligômero hidrolases (PhaY1 e PhaY2) e pelo menos três P3HB despolimerases intracelulares (PhaZa1, PhaZa2 e PhaZd1). Mutantes de B. sacchari afetados na mobilização de P3HB e complementados com genes de Ralstonia eutropha apresentaram um aumento expressivo nas taxas de mobilização de P3HB, especialmente quando o gene phaZa1 foi superexpresso. A superexpressão dos genes phaZa2 ou phaZa3 também conduziu a aumentos nas taxas de mobilização embora em um grau menor que os valores obtidos com phaZa1. Dois mutantes afetados na mobilização de P3HB foram obtidos utilizando o transposon mini-Tn5 (NAM03 e NAM04). NAM03 apresentou interrupção em gene que codifica uma P3HB despolimerase intracelular (PhaZa1). NAM04 apresentou interrupção em gene anotado como serino peptidase LonA. Este pode representar um ativador da mobilização ou uma nova P3HB despolimerase intracelular. / The intracellular poly-3-hydroxybutyrate (P3HB) mobilization system in Burkholderia sacchari was analyzed. A search in Burkholderia spp. genomes identified two oligomer hydrolases (PhaY1 and PhaY2) and at least three intracellular P3HB depolymerase (PhaZa1, PhaZa2 e PhaZd1). B. sacchari mutants affected on P3HB mobilization and complemented by Ralstonia eutropha genes showed an expressive increase on P3HB mobilization rates, especially when phaZa1 was overexpressed. The overexpression of phaZa2 or phaZa3 also increased the mobilization rates though to a lesser extent than phaZa1. Two mutants affected on P3HB mobilization were obtained using the transposon mini-Tn5 (NAM03 and NAM04) .NAM03 was disrupted in a gene encoding an intracellular P3HB depolymerase (PhaZa1). NAM04 was disrupted in a gene annotated as a serine peptidase LonA. This could be a mobilization activator or a new intracellular P3HB depolymerase. Burkholderia sacchari Burkholderia sacchari Biodegradable plastics Biotechnology Biotecnologia Intracellular PHA depolymerase Mobilização de PHA PHA despolimerase Intracelular PHA mobilization Plásticos biodegradáveis Poli-3-hidroxibutirato Polihidroxialcanoatos Poly-3-hydroxybutyrate Polyhydroxylakanoates
6	The interaction between the intracellular endophytic bacterium, Methylobacterium extorquens DSM13060, and Scots pine (Pinus sylvestris L.) Koskimäki, J. (Janne) 17 May 2016 (has links) Abstract To date, plant endophytic bacteria have mainly been studied in roots of crop plants. However, shoot-associated endophytes are less diverse than root-associated ones. Hence, endophytic bacteria of plant shoots evolved different traits, than root colonizers, especially with types of host tissues infected and patterns of growth and development. This study found Methylobacterium extorquens colonized pine seedlings similarly to stem-colonizing rhizobia of other plants. M. extorquens DSM13060 was isolated from meristematic cells in shoot tip cultures of Scots pine (Pinus sylvestris L.). M. extorquens infected the plant stem through epidermis or stomatal apertures, forming infection pockets in the root and stem epidermis, or cortex. Post-infection, thread-like infection structures passed through the endoderm, invading vascular tissues. This led to systemic colonization of above and below ground-parts, observed in in vitro grown Scots pine. A novel mechanism enabling development of endophyte-host symbiosis is discovered within the M. extorquens – Scots pine model. This mechanism involves ability of M. extorquens to produce polyhydroxybutyrates (PHB) to protect itself from host-induced oxidative stress during infection. Upon initial colonization on the host surface, M. extorquens DSM13060 consumes methanol as a carbon source, using it to biosynthesize PHB. PHB are then degraded, upon host infection, by PHB depolymerases (PhaZ) to yield methyl-esterified 3-hydroxybutyrate oligomers. These oligomers have substantial antioxidant activity towards host-induced oxidative stress, enabling the bacterium to bypass host defenses and colonize further tissues. The bacteria can also store PHBs for future protection. The capacity for PHB production and, thus, protection from oxidative stress, is discovered in a wide taxonomic range of bacteria. This study also shows meristematic endophytes are important in growth and development of their hosts. Unlike many bacterial root endophytes, M. extorquens DSM13060 does not induce plant growth through hormones. However, this bacterium can colonize the interior of living host cells, where it aggregates around the nucleus of the host plant. M. extorquens DSM13060 genome encodes nucleomodulins, eukaryotic-like transcription factors, which may intervene in host transcription and metabolism. / Tiivistelmä Kasvin sisällä elävien endofyyttisten bakteerien tutkimus on perinteisesti keskittynyt viljelykasveihin ja niiden juuristoon. Kasvien maanpäällisissä versoissa elävät endofyytit eroavat merkittävästi juuriston bakteereista lajirikkauden suhteen. Versoissa eläville bakteereille on todennäköisesti kehittynyt erilaisia sopeumia kuin juuriston endofyyttilajeille. Endofyyttinen Methylobacterium extorquens DSM13060 elää männyn silmujen kasvusolukossa lisäten isäntäkasvin kasvua. Tässä tutkimuksessa M. extorquens –bakteerin todettiin siirtyvän männyn taimiin samoja mekanismeja käyttäen kuin Rhizobium –suvun typensitojabakteerit. Metylobakteeri tunkeutui isäntäkasviin aktiivisesti soluseinien läpi tai varren ilmarakojen kautta muodostaen mikropesäkkeitä juuren ja varren pinnoille, sekä infektiotaskuja kuorisolukkoon. Bakteeri eteni infektiolankojen avulla endodermin ohi johtosolukoihin, mikä mahdollisti bakteerin siirtymisen muualle taimeen. M. extorquens käytti kasvin pinnalla runsaana olevaa metanolia hiilenlähteenään, varastoiden sen solujen sisäiseksi polyhydroksibutyraatti (PHB) polymeeriksi. Infektion myöhemmissä vaiheissa bakteeri hajotti varastoidun polymeerin PHB-depolymeraasientsyymien (PhaZ) avulla lyhyiksi rasvahappoketjuiksi. Nämä metyloidut 3-hydroksibutyraatin oligomeerit suojasivat bakteeria isäntäkasvin puolustuksen tuottamilta happiradikaaleilta mahdollistaen infektion etenemisen. Tutkimuksessa saatujen tulosten perusteella endofyytin solunsisäinen energiavarasto, PHB, toimii pelkistävänä varastona ympäristön hapettavaa stressiä vastaan. Löytö osoitti uudenlaisen antioksidatiivisen puolustumekanismin, joka on levinnyt laajalle bakteerikunnassa ja liittyy yleisesti bakteerien kykyyn sietää vaikeita olosuhteita. Toisin kuin useat juurissa elävät bakteeriendofyytit, M. extorquens ei lisää isäntäkasvin kasvua tuottamalla kasvihormoneja. Bakteeri kykenee elämään männyn elävien solujen sisällä tumien läheisyydessä. M. extorquens DSM13060 genomi sisältääkin useita geenejä, jotka koodaavat nukleomoduliineja, eukaryoottisolujen säätylytekijöiden kaltaisia entsyymejä, joiden avulla bakteeri todennäköisesti vaikuttaa isäntäkasvin aineenvaihduntaan. Vastaavaa vaikutusmekanismia ei ole aikaisemmin kuvattu endofyyteillä. Tutkimus korostaa aiemmin tuntemattomien meristemaattisten bakteeriendofyyttien merkitystä isäntäkasvin kasvussa ja erilaistumisessa. Methylobacterium PhaZ depolymerase Scots pine endophyte intracellular methylotrophy oxidative stress poly-3-hydroxybutyrate Methylobacterium PhaZ depolymeraasi endofyytti metylotrofia mänty oksidatiivinen stressi poly-3-hydroksibutyraatti solunsisäinen
7	Avaliação do sistema de mobilização de poli-3-hidroxibutirato em Burkholderia sacchari. / Evaluation of poly-3-hydroxybutyrate (P3HB) mobilization system in Burkholderia sacchari. Nuri Andrea Merchan Castellanos 19 October 2010 (has links) O sistema de mobilização intracelular de poli-3-hidroxibutirato (P3HB) em Burkholderia sacchari foi analisado. A busca em genomas de Burkholderia spp. identificou duas oligômero hidrolases (PhaY1 e PhaY2) e pelo menos três P3HB despolimerases intracelulares (PhaZa1, PhaZa2 e PhaZd1). Mutantes de B. sacchari afetados na mobilização de P3HB e complementados com genes de Ralstonia eutropha apresentaram um aumento expressivo nas taxas de mobilização de P3HB, especialmente quando o gene phaZa1 foi superexpresso. A superexpressão dos genes phaZa2 ou phaZa3 também conduziu a aumentos nas taxas de mobilização embora em um grau menor que os valores obtidos com phaZa1. Dois mutantes afetados na mobilização de P3HB foram obtidos utilizando o transposon mini-Tn5 (NAM03 e NAM04). NAM03 apresentou interrupção em gene que codifica uma P3HB despolimerase intracelular (PhaZa1). NAM04 apresentou interrupção em gene anotado como serino peptidase LonA. Este pode representar um ativador da mobilização ou uma nova P3HB despolimerase intracelular. / The intracellular poly-3-hydroxybutyrate (P3HB) mobilization system in Burkholderia sacchari was analyzed. A search in Burkholderia spp. genomes identified two oligomer hydrolases (PhaY1 and PhaY2) and at least three intracellular P3HB depolymerase (PhaZa1, PhaZa2 e PhaZd1). B. sacchari mutants affected on P3HB mobilization and complemented by Ralstonia eutropha genes showed an expressive increase on P3HB mobilization rates, especially when phaZa1 was overexpressed. The overexpression of phaZa2 or phaZa3 also increased the mobilization rates though to a lesser extent than phaZa1. Two mutants affected on P3HB mobilization were obtained using the transposon mini-Tn5 (NAM03 and NAM04) .NAM03 was disrupted in a gene encoding an intracellular P3HB depolymerase (PhaZa1). NAM04 was disrupted in a gene annotated as a serine peptidase LonA. This could be a mobilization activator or a new intracellular P3HB depolymerase. Burkholderia sacchari Biotecnologia Mobilização de PHA PHA despolimerase Intracelular Plásticos biodegradáveis Poli-3-hidroxibutirato Polihidroxialcanoatos Burkholderia sacchari Biodegradable plastics Biotechnology Intracellular PHA depolymerase PHA mobilization Poly-3-hydroxybutyrate Polyhydroxylakanoates
8	Mechanismus plastifikace polyhydroxyalkonátů v mikrobiálních buňkách – inspirace pro vývoj artificiálních nosičových systémů / Plasticizing of polyhydroxyalkanoates in microbial cells - inspiration for development of artificial controlled release systems Liczka, Jan January 2021 (has links) The diploma thesis is focused on the study of the mechanism of plasticization of polyhydroxyalkanoates (PHA) in vivo, focusing mainly on methods of isolation native PHA granules and physical and chemical methods of initiation their phase transitions. The literature search prepared in this work deals with this microbial polyester and further focuses on individual methods of isolating PHA from bacterial cells. The main task of the experimental work was to optimize the isolation process of native PHA granules, as well as to design and test processes that initiate the PHA crystallization in isolated granules, as well as analytical procedures to correctly detect this phase transition. Isolation of PHA granules from Cupriavidus necator was performed by enzymes, centrifugation several times and sonication of the cells. Fourier transform infrared spectroscopy (FTIR) and an enzymatic method in which amorphous PHA is selectively degraded by PHA-depolymerase with turbidimetric detection of its loss in dispersion was used to detect PHA crystallization. Techniques based on fluorescence staining of granules (fluorescence spectroscopy and flow cytometry) were used in a more detailed study of the mechanism of PHA plasticization in granules. The results of the analyzes confirmed, among other things, that the optimized procedure makes it possible to isolate granules in the amorphous state, which remain amorphous even after drying and are comparable to native granules in their basic physicochemical properties.

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