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Development of a recombinant noncytopathic bovine viral diarrhea virus stably expressing enhanced green fluorescent proteinFan, Zhenchuan, Bird, R. Curtis. January 2005 (has links) (PDF)
Thesis(M.S.)--Auburn University, 2005. / Abstract. Vita. Includes bibliographic references.
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Application of green fluorescent protein (GFP) for studing interactions between Ophiostoma piceae and Trichoderma harzianum in freshly sawn Douglas-fir sapwood /Xiao, Ying. January 2004 (has links)
Thesis (Ph. D.)--Oregon State University, 2004. / Printout. Includes bibliographical references. Also available on the World Wide Web.
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Study of low abundance proteins in single cells of Saccharomyces cerevisiae using capillary electrophoresis and ultra sensitivity laser induced fluorescence detection /Mao, Danqian, January 2005 (has links)
Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (leaves 136-140).
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Nonadiabatic molecular dynamics in time-dependent density functional theory with applications to nanoscale materials /Craig, Colleen F. January 2006 (has links)
Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (p. 89-98).
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Investigating cell type specific metabolism using GFP as a reporter proteinRossi, Merja January 2015 (has links)
Metabolic flux analysis (MFA) is a powerful technique for quantifying the intracellular fluxes in central carbon metabolism. It relies on detection of stable isotope labelling from metabolites such as amino acids derived from protein. Current standard techniques are, however, unable to distinguish between different cell types in heterogeneous tissue. The aim of the thesis was to address this problem by developing and validating a strategy using green fluorescent protein (GFP) with cell type specific expression as a reporter protein for investigating the fluxes in specific cell types in the Arabidopsis thaliana root. The fundamental difficulty in applying a reporter protein strategy in a multicellular organism arises from the limited amount of recombinant protein expressed by the cells. The main novel contributions of the work in this thesis are threefold. First, a robust protocol for purification of GFP from the roots of Arabidopsis seedlings and for detection of reliable mass isotopomer distributions from the amino acids derived from GFP are described. Secondly, the reporter protein strategy is validated in this biological system with a focus on showing the data obtained by the use of the reporter protein is equal to that normally obtained from the total protein fraction. To expand on this, stable isotope labelling in isolated root hair cells is explored. These cells are easily isolated and show potential as a model system for cell type specific metabolism. Finally, the experimental data provide evidence for the feasibility of measuring data from specific cell types with appropriate mass spectrometric techniques. Analysis of cell type specific gene expression in this system suggests differences in the primary metabolism of different cell types cannot be ruled out without further investigation. Based on small scale in silico modelling described in this thesis, new solutions capable of providing data on sub-populations of cells are required, if central metabolism of the cell types differs significantly.
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Characterization of the DMCI and Rad51 homologues and the process of meiosis in trichomonas vaginalisIlustrisimo, Tom 01 January 2013 (has links)
Trichomonas vaginal is is the sexually transmitted agent of trichomoniasis. Although the organism is believed to only reproduce via binary fission, genes specific to 5 Meiosis and Homologous Recombination have been identified in its genome. It is unclear whether the organism has the ability to undergo sexual reproduction or if it has lost that ability over time. Aside from meiosis, these genes could be expressed for use in antigenic variation and in the creation or transfer of resistance genes to other cells. In this study, we induced the expression ofDMCl and Rad51 homologues-key players in Homologous Recombination-using a system of tetracycline induction. We localized DMCl to both the cytoplasm and the nucleus, while Rad51 is localized to the nucleus. We performed a DNA strand exchange that suggests DMCl may be capable of DNA strand exchange. We also developed a system to determine whether haploid cells of Trichomonas vaginal is are capable of cytoplasmic fusion through the use of fluorescent proteins. Specifically, this study focuses on a line of Green Fluorescent Protein-expressing cells.
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Expression and Localization of Green Fluorescent Protein in B. abortus strain RB51Liu, Hailan 30 May 2003 (has links)
Brucella abortus is a facultative intracellular bacterial pathogen, which causes abortion in cattle and undulant fever in human. B. abortus strain RB51 (Strain RB51) is the official vaccine for bovine brucellosis in the USA. B. abortus strain RB51 can be used as a vector for the over-expression of its own (homologous) as well as heterologous protective antigens. The immune system can detect these heterologous antigens and produce a response. Expressing a protein in different bacterial compartments has been shown to affect its accessibility to the immune system and the way the antigen is processed by antigen presenting cells. In order to determine if the immune response is affected by the localization of the antigen, green fluorescent protein (GFP) was expressed at three different locations in B. abortus strain RB51, outer-membrane (OM), periplasmic space (PS) and in the cytoplasmic region (CR) of B. abortus strain RB51. This localization was obtained by transforming strain
RB51 with plasmids pBBg18sGFP and pBBgSsGFP, in which the 18 kDa Brucella lipoprotein and the Brucella Cu/Zn SOD protein signal sequences were added to the GFP sequence to cause OM and PS expression respectively. No signal sequences were added to the plasmid pBBgGFP for CR only expression. Expression and localization of GFP in the different compartments in recombinant B. abortus strain RB51 were confirmed by electron microscopy and antibody absorption experiments. Groups of 5 female BALB/c mice each were injected and boosted with three recombinant strains and appropriate controls. Mice were bled and their anti-GFP antibody production was assessed. None of the immunized mice produced specific antibodies against GFP, probably due to the low expression of the heterologous antigen observed in this study by strain RB51 observed in this study. It will be necessary to produce new recombinants which are able to express higher amounts of GFP to answer if localization of heterologous antigen within the recombinant RB51 affects the level of a specific immune response. / Master of Science
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Dynamique cellulaire des protéines de la réplication chez l'archée halophile Haloferax volcanii / Cellular dynamics of the DNA replication proteins in the halophilic archaeon Haloferax volcaniiDelpech, Floriane 17 November 2016 (has links)
Ce travail de thèse porte sur l’étude de la réplication chez les archées, qui constituent le troisième domaine du vivant avec les bactéries et les eucaryotes. L’organisme modèle que nous avons utilisé est l'archée halophile Haloferax volcanii car les outils génétiques disponibles permettent d’exprimer des protéines fusionnées à la Protéine Fluorescente Verte (GFP) dans cet organisme mésophile et aérobe et ainsi de localiser les protéines d’intérêt dans des cellules vivantes. Nous nous sommes ainsi intéressés à la localisation cellulaire de quatre protéines de la réplication qui ont été fusionnées à la GFP et exprimées sous contrôle de leur propre promoteur : (i) la protéine ‘Flap Endonuclease 1’ (FEN1), qui intervient dans la maturation des fragments d’Okazaki, (ii) la protéine ‘Origin Recognition Complex’ (ORC1) impliquée dans la reconnaissance des origines de réplication, (iii) la protéine ‘Proliferating Cellular Nuclear Antigen’ (PCNA), anneau de processivité des ADN polymérases réplicatives, et (iv) la protéine de fixation à l’ADN simple-brin ‘Replication Protein A’ (RPA2) essentielle à la réplication chez H. volcanii. Seule la protéine PCNA n’a pu être exprimée en fusion avec la GFP, suggérant que la protéine fusion n’est pas fonctionnelle. GFP::Orc1 et GFP::Fen1 ont été exprimées dans la cellule mais ne présentent pas de localisation spécifique reflétant un rôle de ces protéines dans la réplication de l’ADN. En revanche des foyers de fluorescence de la protéine fusion GFP::Rpa2 ont été observés, dont le nombre augmente significativement dans des cellules exposées à l’aphidicoline, drogue inhibant la synthèse de l’ADN et induisant ainsi un stress réplicatif. Cependant une localisation différente de la protéine GFP::Rpa2 a été observée lorsque les cellules sont exposés à la phléomycine, qui induit notamment des cassures double-brin de l‘ADN. Dans ces cellules, GFP::Rpa2 forme un foyer de fluorescence massif qui colocalise avec l’ADN compacté dans la grande majorité des cellules observées. Nos résultats suggèrent donc que la localisation spécifique observée pour GFP::Rpa2 reflète son rôle dans la réparation de l’ADN et/ou le redémarrage des fourche de réplication arrêtées. / The aim of this thesis project was to improve our understanding of DNA replication in archaea, the third domain of life with bacteria and eukarya. The model organism chosen for these studies is the halophilic archaea Haloferax volcanii, a mesophilic aerobe for which genetics tools allow studying in living cells the localization of proteins fused to the Green Fluorescent protein (GFP). Four proteins involved in DNA replication were fused to the GFP and expressed under the control of their own promoter: (i) the ‘Flap Endonuclease 1’ (FEN1), involved in Okazaki fragments maturation, (ii) the ‘Origin Recognition Complex’ (ORC1), involved in DNA replication origin recognition, (iii) the ‘Proliferating Cellular Nuclear Antigen’ (PCNA), processivity factor of replicative DNA polymerases, and (iv) the ‘Replication Protein A’ (RPA2), single-stranded DNA binding protein essential for DNA replication in H. volcanii. Only the PCNA fusion to the GFP was not successful, suggesting that the GFP hinders essential roles of PCNA in DNA replication. Fen1 and Orc1 were successfully fused to the GFP and expressed in living cells, but specific localization in cells related to growth phase, reflecting different replication dynamics, were not observed. In contrast, we could observed fluorescent foci formed by the fully functional GFP::Rpa2 protein that actively responded to DNA damage in H. volcanii cells. The number of these fluorescent foci per cell was constant during cell growth but it significantly increased in cells exposed to aphidicoline, which inhibits DNA synthesis during replication. When cells were treated with phleomycine, a DNA damaging agent mainly causing double-strand breaks, formation of a massive fluorescent focus coinciding with DNA compaction was observed. Our results suggest that the specific cellular localization of GFP::Rpa2 observed reflects Rpa2 roles in DNA repair and/or DNA replication fork restart.
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Cloning of the gfp (green fluorescent protein) gene downstream of the ldh promoter in a bacteriocin-sensitive strain of Lactobacillus sakei to serve as a reporter strain in bacteriocin studiesLiss, Petronella Francina 12 1900 (has links)
Thesis (MSc)--Stellenbosch University, 2003. / ENGLISH ABSTRACT: Lactobacillus plantarum 285, isolated from sorghum beer, produces bacteriocin 285, which
displays activity against several food spoilage organisms. For future application of
bacteriocin 285 in the food industry, it was important to characterize the peptide and identify
the genes encoding its production. The effect of bacteriocin 285 on sensitive cells was
determined through the use of an indicator (sensitive) organism, Lactobacillus sakei DSM
20017. The indicator strain was genetically modified to express GFP (green fluorescent
protein), with the aim of quantifying the antibacterial activity of bacteriocin 285 as a function
of GFP fluorescence.
Bacteriocin 285 proved to be identical to plantaricin 423 produced by L. plantarum 423.
Plantaricin 423 is a class lIa bacteriocin and displays antimicrobial activity towards a broad
spectrum of bacteria, including several food spoilage organisms. The sensitivity of L. sakei
DSM 20017 towards antibacterial peptides produced by Lactobacillus curvatus DF38, L.
plantarum 285, Lactobacillus casei LHS and Lactobacillus salivarius 241 is not limited to the
growth stage of the organism. Cells remained sensitive to all four of these bacteriocins, from
lag phase to late exponential growth. To inhibit growth of up to 90% of the cells of L. sakei
DSM 20017, 1 AU/ml bacteriocin 285 (7 ng/ml) of partially purified bacteriocin 285 was
required. However, to kill all viable cells of L. sakei DSM 20017, 16 AU/ml (110 ng/ml) of
partially purified bacteriocin 285 was required.
The gfpuv gene, encoding GFPuv, was cloned downstream of the Idh promoter and
successfully expressed in L. sakei DSM 20017. However, GFPuv fluorescence could not be
used as a direct method to quantify the antimicrobial activity of bacteriocin 285, since cells of
strain DSM 20017 remained fluorescent for prolonged periods after treatment with lethal
concentrations of the bacteriocin. The non-viability of the cells was confirmed with
epifluorescence microscopy and a L1VE/DEAD® Baclight™ Bacterial Viability Probe. Cells
that were stained with the viability probe indicated that the majority of untreated L. sakei
DSM 20017 cells were viable. However, treatment of strain DSM 20017 with 16 AU/ml
bacteriocin 285 rendered all visible cells non-viable. / AFRIKAANSE OPSOMMING: Lactobacillus plantarum 285 wat uit sorgumbier geïsoleer is, produseer bakteriosien 285. Die
bakteriosien toon aktiwiteit teen verskeie organismes wat voedselbederi veroorsaak. Vir
toekomstige aanwending van bakteriosien 285 in die voedselindustrie was dit belangrik om
die peptied te karakteriseer en die gene wat vir die produksie daarvan kodeer, te identifiseer.
Die effek van bakteriosien 285 op sensitiewe selle is bepaal deur die gebruik van 'n indikator
(sensitiewe)-organisme, Lactobacillus sakei DSM 20017. Die indikator-organisme is geneties
verander om die GFP (groen fluoreserende proteïen) uit te druk. Die doel was om die
antibakteriese aktiwiteit van bakteriosien 285 te kwantifiseer as 'n funksie van GFP
fluorisensie.
Bakteriosien 285 is identies aan plantarisien 423 wat deur L. plantarum 423 produseer word.
Plantarisien 423 is 'n klas Iia bakteriosien en vertoon antimikrobiese aktiwiteit teenoor 'n wye
verskeidenheid bakterieë, insluitende verskeie organismes wat voedsel bederf. Die
sensitiwiteit van L. sakei DSM 20017 teenoor antibakteriese peptiede wat deur Lactobacillus
cutveius DF38, L. plantarum 285, Lactobacillus casei LHS en Lactobacillus salivarius 241
geproduseer word, word nie beïnvloed deur die groeifase van die organisme nie. Selle het
sensitief gebly teenoor al vier die bakteriosiene van sloer- tot laat eksponensiële groei. Om
groei van tot 90% van L. sakei DSM 20017 selle te inhibeer, word 1 AU/ml (7 ng/ml)
gedeeltelik gesuiwerde bakteriosien 285 benodig. Om alle lewensvatbare L. sakei DSM
20017 selle te dood, word 16 AU/ml (110 ng/ml) gedeeltelik gesuiwerde bakteriosien 285
benodig.
Die gfpuv-geen, wat GFPuv kodeer is stroomaf van die Idh-promoter gekloneer en suksesvol
in L. sakei DSM 20017 uitgedruk. GFPuv fluoresensie kon nie as direkte metode gebruik word
om die antimikrobiese aktiwiteit van bakteriosien 285 te bepaal nie, aangesien die selle van
L. sakei DSM 20017 fluoreserend gebly het lank na behandeling met dodelike konsentrasies
van die bakteriosien. Die lewensvatbaarheid van die selle is bevestig deur epifluoresensiemikroskopie
en 'n LlVE/DEAD® Bac/ight™ bakteriese lewensvatbaarheidspeiler. Selle van L.
sakei DSM 20017 wat deur die peiler gekleur is, het gewys dat die meeste selle wat nie deur
bakteriosien 285 behandel was nie, lewensvatbaar was. Behandeling van L. sakei DSM
20017 met 16 AU/ml bakteriosien 285 het al die sigbare selle gedood.
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cDNA?GFP Fusion Libraries for Analyses of Protein Localization in Mouse Stem CellsMurray, Heather January 2005 (has links)
Stem cells have great potential value for treating a number of diseases and conditions, including diabetes, Parkinson's, and spinal cord injuries. Applying stem cells for therapeutic purposes will require an in-depth understanding of their biology, not only of the genes they express, but also the functions of the proteins encoded by the genes. The goal of the project presented in this thesis was to develop a method for high-throughput analyses of protein localization in mouse stem cells. Localization information can provide insight into the functions and biological roles of proteins. <br /><br /> One means of studying protein localization involves creating proteins with a green fluorescent protein (GFP) reporter gene and analyzing their localization using fluorescence microscopy. The research outlined in this thesis focused on developing a system to create a large number of GFP-tagged proteins by constructing a cDNA?GFP fusion library. This involved exploring methods for optimizing cDNA synthesis, designing a retroviral vector (pBES23) for the expression of cDNA?GFP fusions in mouse stem cells, and constructing a cDNA?GFP fusion library in this vector using R1 mouse embryonic stem cell mRNA. The library constructed was not successfully delivered to target cells for GFP-tagged protein expression; it was therefore not possible to characterize protein localization in mouse stem cells. Suggestions are given as to how the methods used in this thesis might be optimized further.
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