Global ETD Search

301	étude structurale et fonctionnelle de la protéine a1 du bactériophage t5 : une dnase octamérique originale / structural and functional study of bacteriophage t5 a1 protein : an original octameric dnase Zangelmi, Léo 06 December 2018 (has links) Les bactériophages neutralisent les systèmes de défense et détournent les fonctions vitales de leur hôte pour favoriser leur multiplication. Les gènes de phages qui gouvernent cette prise de contrôle de l’hôte restent mal connus, pourtant leur caractérisation présente un intérêt majeur pour mettre à jour des fonctions bactériennes spécifiquement ciblées par les phages et pour concevoir de nouveaux agents antibactériens.Le phage T5 injecte son ADN dans la bactérie Escherichia coli en deux étapes. Seuls les gènes précoces codés par 8% du génome entrent dans la cellule et le transfert s’arrête. Leur expression induit la dégradation du chromosome de l’hôte et l’inactivation de ses systèmes de restriction et de réparation de l’ADN. Après quelques minutes, le reste de la molécule d’ADN est injecté, ce qui permet la production de nouveaux phages. Deux gènes précoces A1 et A2 ont été identifiés comme essentiels pour la reprise du transfert de l’ADN et A1 est également nécessaire pour induire la dégradation de l’ADN de l’hôte. A1 et A2 sont les deux seuls gènes connus pour être impliqués dans la régulation de ce système original d’infection, mais leur fonction n’a jamais été identifiée.Ma thèse porte sur la caractérisation fonctionnelle et structurale des protéines A1 et A2. J’ai purifié A1 et démontré in vitro qu’elle avait une activité DNase dépendante du manganèse. Sa structure atomique a été résolue par cryomicroscopie électronique à 3.01 Å de résolution, montrant une organisation octamérique de symétrie D4 inédite pour une DNase. Chaque monomère (61kDa) contient un domaine exonuclease dont le site actif lie deux ions Mn2+ et qui s’apparente au site catalytique des domaines exonucléases de la DNA polymerase II et des DNAses associées aux systèmes de recombinaison homologue et de réparation de l’ADN comme Mre11. En construisant différents mutants de A1, j’ai identifié certains acides aminés essentiels pour l’activité catalytique et, par des expériences de complémentation fonctionnelle, j’ai montré que cette activité était indispensable pour l’infection. L’ensemble de ces résultats suggèrent que A1 est la DNase, jusqu’ici inconnue, responsable de la dégradation massive du génome de l’hôte au tout début de l’infection. Enfin, j’ai observé que la production de A1 pendant l’infection induit une forte activité recombinase. De nombreux autres bactériophages qui n’appartiennent pas à la famille des T5virus produisent également une protéine similaire à A1 dont la fonction n’a jamais été identifiée. Ce travail est un premier pas vers la compréhension de son rôle dans le mécanisme général d‘infection par les phages. Une deuxième partie de cette thèse porte sur la caractérisation structurale de A2. Des recherches de similarité indiquent la présence d’un domaine Helix-Turn-Helix typique des régulateurs transcriptionnels. J’ai purifié A2 et montré que cette protéine de 14 kDa est un dimère en solution. La caractérisation des propriétés biochimiques de A2 a permis de débuter l’étude de sa structure par RMN.Les résultats de ma thèse ont révélé la structure originale d’une DNase de bactériophage qui contrôle la dégradation du génome bactérien et la régulation du transport de l’ADN viral au début du cycle infectieux. Ces résultats soulèvent des questions intrigantes : comment l’ADN de T5 est-il protégé de l’activité DNase de A1 ? Comment A1 et A2 interagissent-elles lors des étapes de prise de contrôle de l’hôte ? / Bacteriophages defeat bacterial defences and hijack host cell machineries to establish a favourable environment for their multiplication. Early-expressed viral genes that govern host takeover are highly diverse from one phage to another and most of them have no assigned function. They thus represent a pool of novel genes whose products potentially subvert bacterial cell vital functions and could help in designing new antibacterial strategies.T5 phage uses a unique 2-step mechanism to deliver its DNA into its host Escherichia coli. At the onset of the infection, only 8 % of the genome enter the cell before the transfer temporarily stops. Expression of the genes encoded by this DNA portion leads to host chromosome degradation and inactivation of host restriction and DNA mending systems. After a few minutes, T5 DNA transfer resumes, allowing further phage multiplication. A1 and A2 are early genes required for DNA transfer completion and A1 is also necessary to trigger host DNA degradation. A1 and A2 are the only two genes known to be involved in the regulation of this original infection system, but their function yet remains to be characterized.The objectives of this work were to characterize the function and structure of A1 and A2 proteins. I have purified the A1 protein and shown that it has a manganese-dependent DNase activity in vitro. Cryo Electron Microscopy at 3.01 Å resolution unravelled its structure, showing an octameric organization with a D4 symmetry, which is unprecedented for a DNase. Each monomer (61 kDa) carries an exonuclease domain harbouring an active site with two Mn2+ ions. This site is similar to those from the exonuclease domain of the DNA polymerase II and from DNases involved in DNA mending and recombination events like Mre11. I identified essential catalytic residues for the DNase activity and demonstrated that this activity is crucial for infection by engineering A1 mutant proteins and by doing functional complementation assays. Taken together, my results suggest that A1 could then be the elusive DNase responsible for the massive host genome degradation observed during T5 phage infection. Eventually, I uncovered a recombinase activity associated to A1 production during infection. Similar proteins to A1 with unknown functions are produced in several other bacteriophages outside of the T5virus family. This work is a first step towards understanding the role of this protein in the general mechanism of infection by bacteriophages. In a second part, I worked on the structural characterisation of A2 protein. Similarity searches revealed a helix-turn-helix domain typically found in transcriptional regulators. I purified and demonstrated the dimeric organisation of this 14-kDa protein in solution. This initial characterization of A2 has opened avenues for further NMR studies.During my Ph.D., I uncovered the structure of an original bacteriophage DNase that controls bacterial genome degradation and that regulates viral DNA transport at the beginning of the infectious cycle. These results open the intriguing question about the mechanism for T5 DNA protection from A1 DNase activity as well as about the interplay between A1 and A2 during the host takeover. Bactériophage T5 Dnase Exonucléase Structure Cryomicroscopie électronique Saxs Bacteriophage T5 DNase Exonuclease Structure Cryo Electron Microscopy Saxs
302	Advancing Phage Genomics and Honeybee Health Through Discovery and Characterization of Paenibacillaceae Bacteriophages Merrill, Bryan Douglas 01 June 2015 (has links) (PDF) The Paenibacillaceae family of bacteria includes two species known to infect the hives of honeybees, Paenibacillus larvae and Brevibacillus laterosporus. P. larvae, the causative agent of American Foulbrood (AFB) causes a lethal infection of honeybee larvae, while B. laterosporus is a secondary invader following European Foulbrood (EFB) infection. Increasing antibiotic resistance of P. larvae bacteria has prompted a search for alternative treatment methods for this disease. Bacteriophages are the most diverse life forms on earth and can provide important insights about the bacterial hosts they infect. However, few Paenibacillaceae phages have been isolated or characterized. In this study, the first B. laterosporus phages are characterized with respect to host range, structural morphology, and sequence similarity. The isolation and characterization of many P. larvae field isolates together with 38 novel P. larvae phages made possible the first broad phage typing study of P. larvae. Phage typing data indicated that P. larvae strains tested could be categorized into one of two groups. Comparative genomics of bacteriophages was made easier by modifying Phamerator to make it broadly accessible and usable to phage researchers throughout the world. Additionally, raw sequencing data can now be used to identify phage DNA packaging strategies that are indicative of a phage’s physical ends. Using these data, phage genomes can be published in an orientation and complementarity that reflects the physical structure of the phage chromosome, providing order and consistency that will benefit all future phage researchers. Paenibacillus larvae American Foulbrood honeybees Brevibacillus laterosporus bacteriophage genomics phage typing Phamerator phage packaging strategy DNA sequencing Microbiology
303	The Effects of Polymorphisms of Viral Protein R of HIV-1 on the Induction of Apoptosis in Primary Cells and the Characterization of Twelve Novel Bacillus anthracis Bacteriophage Fairholm, Jacob D. 03 August 2022 (has links) Viral protein r (Vpr) of Human immunodeficiency virus type 1 (HIV-1) plays an important role in the ability of the virus to infect cells and cause disease. Two polymorphisms to Vpr have been shown to result in differences in disease progression in infected individuals. R36W tends to result in rapid disease progression while R77Q results in long-term non-progression. In order to better understand how these polymorphisms result in these different disease phenotypes, our lab has recently shown that in cell culture, the R36W polymorphism results in increased viral replication and greater induction of cell death. On the other hand, infection with R77Q results in increased G2 cell cycle arrest and increased induction of apoptosis. In this thesis, we have attempted to study how these two polymorphisms affect the ability of HIV-1 to cause cell death in primary CD4+ cells. We show that infection by a Vpr knockout virus results in increased apoptosis while infection with R77Q and R36W result in decreased apoptosis. Additionally, R77Q infection results in increased p24 production. Further, we attempted create a Rag2-/- γc-/- humanized mouse model in order to better study roles of these polymorphisms in vivo. An additional goal of this thesis was to characterize twelve novel Bacillus anthracis bacteriophage. B. anthracis is gram positive, anaerobic, rod best known for being the causative agent of anthrax. Bacteriophage, viruses that infect bacteria, have been used to identify bacterial contamination and to treat infection. Herein, we report the isolation, sequencing, and characterization of twelve novel phages that infect B. anthracis. The genomes were annotated using DNA Master and BLASTp. Hypothetical proteins were analyzed with Phyre2 to predict possible functions based on protein structure, revealing over 100 new predicted functions. Dotplot generation showed that these phages group into four distinct clusters. By running the major portal protein of one representative of each cluster through BLASTp, we have identified the closest relatives to our novel phages and placed them into their respective genera and groups. HIV-1 Vpr AIDS Rag2-/- γc-/- humanized mice apoptosis primary CD4+ cells Bacillus anthracis bacteriophage Life Sciences
304	Lytic Bacteriophages and Lactic Acid As Processing Aids Against Salmonella spp. and Escherichia coli O157:H7 on Marinated and Tenderized Pork Loins Li, Sherita 01 March 2022 (has links) (PDF) Within the last decade, pork consumption has steadily increased and continues to be the most consumed meat globally. However, pathogenic bacterial strains resistant to antibiotics have also been increasingly found in pig farms, animals, and the environment. Bacterial food poisoning cases due to Salmonella spp. and Escherichia coli (E. coli) O157:H7 appear to be linked with a variety of pork products. The meat industry has recognized that research is needed to combat the multi-drug resistance in foodborne pathogens with alternative methods of control. This study evaluated the effects of both E. coli- and Salmonella-specific lytic bacteriophages and lactic acid (LA) on E. coli O157:H7, Salmonella Enteritidis, Salmonella Montevideo, and Salmonella Heidelberg growth in raw pork loins ready for marination. The efficacy of the treatments was determined after 1 h of application and marination. Lytic bacteriophage 5% significantly (PSalmonella spp. population by 2.30 log CFU/cm2 when compared with the initial surface attachment. Moreover, the combined treatment of LA 2.5% + phage 5% significantly (PSalmonella population by 2.35 log CFU/cm2 after 1 hour of attachment. In the post-tenderization surface samples, the combination of both phage and LA showed (PP>0.05) when analyzing the translocation of Salmonella spp. on pork loins. Similar treatment efficacy results were observed in the application of E. coli O157:H7 on pork. Following antimicrobial treatments, both control and treated loin samples were enumerated after 1 h at 4°C. Both the lytic bacteriophage 5% and the combination of lytic bacteriophage 5% with lactic acid 2.5% had a significant reduction of E. coli O157:H7 on surface attachment after 1 h of treatment application. Lytic bacteriophage 5% and Lactic acid 2.5% significantly (P < 0.05) reduced the surface bacterial population by 1.89 log CFU/cm2. Lytic bacteriophage 5% alone significantly (P < 0.05) reduced the surface bacterial population by 1.90 log CFU/cm2 when compared with the initial surface attachment groups. Moreover, in the post-tenderization surface samples, lytic bacteriophage 5% and the combination of lytic bacteriophage 5% with lactic acid 2.5% were the only treatments that had a significant reduction (P < 0.05) when compared with the control group. Interestingly, lactic acid 2.5% was the only treatment that had a significant reduction (P < 0.05) of 0.76 log CFU/cm2 when analyzing the translocation of pathogens on pork chops. Lytic Bacteriophage Lactic Acid Escherichia Coli O157:H7 Salmonella spp. Raw Pork Loin Food Microbiology Food Science
305	Isolation and Characterization of Phages Infecting Streptomyces azureus Sulaiman, Ahmad M. 05 1900 (has links) Isolating novel phages using Streptomyces azureus, which produces antibiotic thiostrepton, as a host, and characterizing the genomes may help us to find new tools that could be used to develop antibiotics in addition to contribute to the databases of phages and specifically, Streptomyces phages. Streptomyces phages Alsaber, Omar, Attoomi, Rowa, and ZamZam were isolated using during this study. They were isolated from enriched soil and sequenced by Illumina sequencing method. They were isolated from three different geographical regions. They are siphoviridae phages that create small clear plaques with a diameter of approximately 0.5-1 mm, except for Rowa which has cloudy plaques, and they have varied sizes of their heads and tails. ZamZam was not characterized at this time. The sequencing shows that they are circular genome with 3' sticky overhang and various genomes' sizes with high percentage of GC content with the average of 66%. Alsaber was classified under sub-cluster BD3, while Omar was categorized under sub-cluster BD2. They share the same cluster of Cluster BD. Rowa was placed in Cluster BL and Attoomi is currently a singleton that does not fit into an established cluster. Alsaber yields 76 putative genes with no tRNA, Omar 81 putative genes with 1 tRNA. Attoomi 53 putative genes with no tRNA, and Rowa with 61 orfs and 7 tRNA. Rowa also was a putative temperate phage due to its lysogenic activity, and Row was not able to reinfect the lysogenic strain, S. azureus (Rowa). All of the isolated phages infected S. indigocolor, while only Attoomi and Rowa were able to infect S. tricolor. Upon completion of this project, we acquired more data and understanding of S. azureus phages and Actinobacteriophage in general, which will expand the scale of future research of Streptomyces bacteriophages. Bacteriophage (Phage) Streptomyces azureus Isolation Characterization Biology, Molecular Chemistry, Biochemistry Biology, Microbiology Bacteriophages. Streptomyces. Genomes. Gene mapping.
306	Analysis of the Interactions between the 5' to 3' Exonuclease and the Single-Stranded DNA-Binding Protein from Bacteriophage T4 and Related Phages Boutemy, Laurence S. 14 October 2008 (has links) No description available. Biochemistry DNA replication protein-protein interactions protein-DNA interactions macromolecular crystallography SAXS RNase H 32 protein bacteriophage T4
307	Chip-Calorimetric Monitoring and Biothermodynamic Analysis of Biofilm Growth and Interactions with Chemical and Biological Agents / Chipkalorimetrisches Monitoring und Biothermodynamische Analyse von Biofilmen und ihren Wechselwirkungen mit chemischen und biologischen Agentien Mariana, Frida 16 February 2016 (has links) (PDF) Over the last years, varieties of technologies for biofilm analysis were developed and established. They work on different principles and deliver information about biofilms on different information levels. In this work, chip-calorimetry was applied as an analytical tool that measures heat produced from biofilms. Any change of metabolism in biofilms is reflected by a changed heat flow. The heat, which is the integral of the heat flow vs. time, is quantitatively related to the growth stoichiometry of the biofilm, as described by the Hess’ Law. The heat flow is related to the growth kinetics with the reaction heat as proportionality factor. The results from the calorimetric measurement thus, deliver general information about growth stoichiometry and kinetics. The other interpretation of calorimetric results bases on the assumed proportionality between heat flow and oxygen consumption rate (- 460 kJ/mol ). This ratio is called oxycaloric equivalent. Because in case of aerobic growth the majority of oxygen is consumed in catabolic processes during the electron transport phosphorylation, calorimetry is assumed to provide information about the catabolic side of the metabolism. The newly developed chip-calorimeter applied in this work is much more suitable for biofilm studies compared to conventional microcalorimeters due to the flow-through design of the calorimetric chamber. The measurement of undisturbed growing biofilms and the comparison with conventional biofilm analysis tools (i.e. plate counts, confocal laser scanning microscopy (CLSM), and the determination of intermediates’ concentrations (e.g. ATP)) demonstrate the proper functionality of the calorimetric method and the related cultivation procedure by delivering measurement results in the range of literature values. However, when the biofilms were challenged with antimicrobial agents i.e. antibiotics, bacteriophage, and predatory bacteria, the calorimetric results surprisingly deviated from the reference analyses. By combining the results of the calorimetric and reference analyses, additional information about the antimicrobial effects on biofilms can be acquired. Combination of heat measurement and plate counts, which is one of the most conventional approaches, demonstrated that antimicrobials (especially the bactericidal acting kanamycin) could cause the loss of culturability while the cells were still metabolically active. The measurement of ATP content resulted in values out of the typical range, which indicated that antimicrobial treatments disturbed the cellular ATP regulation and the ATP concentration was no longer linearly correlated to the cell number. ATP measurements are therefore not suitable for antimicrobial susceptibility testing. The comparison of heat profiles with the biovolume determined by quantification of microscopic images shows an elevated cell specific heat production rate after the introduction of some antimicrobials (antibiotics and bacteriophage). In case of antibiotics, this can be explained as a consequence of the bacterial defense mechanisms. Most of the described defense mechanisms against antibiotics need biological energy and therefore drive the electron transport phosphorylation (ETP). In case of biofilm treatments with bacteriophage, the trigger of increasing ETP might be the synthesis of phage proteins, hull material, and genetic information molecules. In aerobic conditions, oxygen is used as terminal electron acceptor. Elevated ETP leads therefore to an increase in oxygen consumption, which correlates to the heat production using oxycaloric equivalent as a factor. These correlations explain the increase of cell specific heat productions as biofilms were challenged by antibiotics and bacteriophage. However, also a decrease of specific heat production was observed (in case of predatory bacteria). Here, the predatory bacteria activity caused various damages in host cells, including the interruption of ETP. With these experiments, chip-calorimetry was demonstrated as a promising complementary tool in biofilm research, which provides deeper insights about metabolic activity and alterations. It benefits from the noninvasive handling and the online, real-time measurement that allow the method to be applied for monitoring purposes. Furthermore, its miniaturized dimension allows easy integration in more complex analytic systems and also reduces experiment costs with minimal media/chemical consumption. This thesis also demonstrates the potential development of chip-calorimetry to be more suitable for routine analyses. The use of superparamagnetic beads as matrix to grow biofilms allows regulated transfer of biofilm samples into and from the measurement chamber. This was an initial step towards automation and higher-throughput analysis. One further outcome of the thesis is based on the highly interesting fact about the elevated heat production rate of the host cells induced by the phage infection observed in the chip- calorimetric experiments. The volume specific detection limit of the chip-calorimeter is lower compared to a commercial microcalorimeter. Thus, the infection effect of phages was additionally measured in microcalorimeter to get better quantitative information about the thermal effect of the infection. The results showed that the immediate heat increase after the addition of phage into the solution of the host cells appeared to be quantitatively related to the infection factor, MOI (Multiplicity of Infection). Unfortunately, microcalorimetric measurements in closed ampoules are often subjected to the oxygen limitation. Thus, this problem of microcalorimetric measurement has been addressed. The combination of experimental results and mathematical modeling showed that the rate of metabolism in the static ampoules is defined by the diffusion rate of oxygen into media. This factor has to be considered while designing biological experiments in closed calorimetric measuring chambers and interpreting the calorimetric results for their biological meaning. Some possible solutions to overcome the oxygen bioavailability problem are e.g. to design the experiments with low biomass, or by using media with elevated density to float the biomass at the interface to air and thus to reduce the diffusion path. Chip-Kalorimetrie Kalorimetrie Biofilm Biofilmen-Quantifikation Antibiotika räuberische Bakteria Bakteriophage Mikrokalorimetrie chip-calorimetry calorimetry biofilm biofilm quantification antibiotics predatory bacteria bacteriophage microcalorimetry ddc:620 rvk:WF 1350
308	Structural and biophysical studies of RNA-dependent RNA polymerases Wright, Sam Mathew January 2010 (has links) RNA-dependent RNA polymerases (RdRps) play a vital role in the life cycle of RNA viruses, being responsible for genome replication and mRNA transcription. In this thesis viral RdRps (vRdRps) of dsRNA bacteriophage phi6 (phi6 RdRp) and Severe Acute Respiratory Syndrome (SARS) coronavirus [non structural protein 12 (NSP-12)] are studied. For SARS polymerase NSP-12, a library-based screening method known as ESPRIT (Expression of Soluble Protein by Random Incremental Truncation) was employed in an attempt to isolate domains of NSP-12 that express solubly in Escherichia coli (E. coli) and are thereby suitable for structural studies. This experiment identified for the first time in a systematic fashion, conditions under which the SARS polymerase could be solubly expressed at small scale and allowed mapping of domain boundaries. Further experiments explored different approaches for increasing expression levels of tractable fragments at large scale. Bacteriophage phi6 RdRp is one of the best studied vRdRps. It initiates RNA synthesis using a de novo mechanism without the need for a primer. Although formation of the de novo initiation complex has been well studied, little is known about the mechanism for the transition from initiation to elongation (i.e. extension of an initiated dinucleotide daughter strand). In the phi6 RdRp initiation complex the C-terminal domain (CTD) blocks the exit path of the newly synthesised dsRNA which must be displaced for the addition of the third nucleotide. The crystal structure of a C-terminally truncated phi6 RdRp (P2T1) reveals the strong non-covalent interactions between the CTD and the main body of the polymerase that must be overcome for the elongation reaction to proceed. Comparing new crystal structures of complexes of both wild-type (WT) and a mutant RdRp (E634 to Q, which removes a salt-bridge between the CTD and main body of the polymerase) with various oligonucleotides (linear and hairpin), nucleoside triphosphates (NTPs) and divalent cations, alongside their biophysical and biochemical properties, provides an insight into the precise molecular details of the transition reaction. Thermal denaturation experiments reveal that Mn2+ acquired from the cell and bound at the phi6 RdRp non-catalytic ion site sufficiently weakens the polymerase structure to facilitate the displacement of the CTD. Our crystallographic and biochemical data also indicate that Mn2+ is released during this displacement and must be replaced for the elongation to proceed. Our data explain the role of the non-catalytic divalent cation in vRdRps and pinpoint the Mn2+-dependent step in viral replication. In addition, by inserting a dysfunctional Mg2+ at the non-catalytic ion site for both WT and E634Q RdRps we captured structures with two NTPs bound within the active site in the absence of Watson-Crick base pairing with template and could map movements of divalent cations during preinitiation through to initiation. Oligonucleotides present on the surface of phi6 RdRp allowed mapping of key residues involved in template entry and unwinding of dsRNA; these preinitiation stages have not been observed previously. Considering the high structural homology of phi6 RdRp with other vRdRps, particularly from (+)ssRNA hepatitis C virus (HCV), insights into the mechanistic and structural details of phi6 RdRp are thought to be relevant to the general understanding of vRdRps. 571.4
309	Production of Porcine Single Chain Variable Fragment (SCFV) selected against a recombinant fragment of Porcine Reproductive and Respiratory Syndrome virus non structural protein 2 Koopman, Tammy L. January 1900 (has links) Master of Science / Department of Diagnostic Medicine/Pathobiology / Richard 'Dick' Hesse / Carol Wyatt / Over the last two decades molecular laboratory techniques have enabled researchers to investigate the infection, replication and pathogenesis of viral disease. In the early eighties, Dr. George Smith developed a unique system of molecular selection. He showed that the fd bacteriophage genome could be manipulated to carry a sequence of DNA coding for a protein not contained in the phage genome. Infection of the recombinant bacteriophage or phagemid into a specific strain of the bacterium, Escherichia coli, produced progeny phage with the coded protein displayed as a fusion with the phage's coat protein. Antibody phage display utilizes the same technology with the DNA encoding an antibody fragment. The DNA insert can carry the information to produce either a single chain variable fragment (scFv) producing the heavy chain variable and light chain variable (VH-VL) portion or a Fab fragment which also contains the heavy chain constant 1 with the light chain constant (CH and CL) portion of an antibody. Screening an antibody phage display library has the possibility of producing an antibody not produced in the normal course of immune selection. This decade also saw the emergence of a viral disease affecting the porcine population. The Porcine Reproductive and Respiratory Syndrome virus (PRRSV) has been one of the most costly diseases affecting the pig producer. Molecular investigations found that PRRSV is a single, positive-stranded RNA virus which codes for five structural and 12-13 nonstructural proteins producing an enveloped, icosahedral virus. An interesting characteristic of PRRSV is the ability to produce infective progeny with genomic deletions, insertions and mutations within the nonstructural protein 2 (nsp2). With this knowledge, many researchers have produced marker vaccines containing fluorescent tags with the hope of developing a DIVA (Differentiate Infected from Vaccinated Animals) vaccine. In my Master‟s studies, I studied the techniques of antibody phage display technology and how to apply these methods to producing scFvs which recognize a recombinant PRRSV nsp2 fragment protein and the native protein during infection of MARC-145 cells. Phage display Single chain variable fragment (scFv) M13 bacteriophage Immunology (0982) Molecular Biology (0307) Virology (0720)
310	Genômica comparativa de Xylella fastidiosa: diversidade do pangenoma e análise de genes de patogenicidade / Comparative genomics of Xylella fastidiosa: pan-genome diversity and analysis of patogenicity genes Santana, Wesley Oliveira de 04 February 2013 (has links) O gênero Xylella é composto de uma única espécie, Xylella fastidiosa, bactéria Gram-negativa, não flagelada, que coloniza o xilema de uma diversidade de plantas cultivadas e silvestres em várias partes do mundo. Em algumas dessas plantas, a bactéria é considerada agente causal de doenças, como a Clorose Variegada do Citros em laranjeiras, a Doença de Pierce das videiras e escaldadura da folha de cafeeiro. Onze diferentes cepas de X. fastidiosa, isoladas de distintos hospedeiros, já tiveram seus genomas sequenciados, entre essas, as cepas 9a5c, isolada de laranjeira, e Temecula 1, isolada de videira. Análises desses genomas indicam uma razoável variabilidade entre suas respectivas sequências e evidenciam vários genes associados a mecanismos de virulência e patogenicidade desta bactéria. No presente trabalho descrevemos o sequenciamento, a montagem e a anotação dos genomas das cepas U24d e Fb7, isoladas de laranjeiras, e da cepa 3124 isolada de cafeeiro, os quais apresentam, respectivamente 2.681.334 pb, 2.733.974 pb e 2.748.594 pb. Destas, apenas a cepa U24d apresenta um plasmídeo, o qual é idêntico ao pXF51 previamente identificado na cepa 9a5c. O genoma da cepa U24d é praticamente colinear ao genoma da cepa 9a5c enquanto que os genomas das cepas Fb7 e 3124 apresentaram maior colinearidade com a cepa Temecula1. Entre as diversas alterações encontradas nas análises comparativas destes genomas, destacamos a inserção no gene pilQ verificada no genoma da cepa U24d. Essa mutação causa ausência do pilus do tipo IV com consequente deficiência na motilidade twitching, sendo que plantas infectadas com a cepa U24d apresentam sintomas localizados restritos ao ponto de inoculação. Na cepa Fb7, detectamos a ausência de formação de biofilme no cultivo in vitro possivelmente devido ausência da expressão dos transcritos de mrkD e pspA, que codificam respectivamente adesina do pilus curto e adesina similar à hemaglutinina. Postulamos que estes genes não são expressos em decorrência de um defeito na via de sinalização de DSF (Fator de Sinalização Difusível) reflexo de uma mutação em rpfC no genoma de Fb7. Assim como as demais cepas de X. fastidiosa, também os genomas de U24d, Fb7 e 3124 apresentaram elevado conteúdo de Elementos Genéticos Móveis (EGM), que aparecem em maior número nas cepas sul-americanas. Os estudos do pangenoma de X. fastidiosa mostraram que essa espécie tem um genoma aberto e grande parte dos genes de EGMs correspondem a genes acessórios. A grande quantidade de EGMs em X. fastidiosa pode estar relacionada a falta do sistema CRISPR/cas completo, um provável resultado de eventos de erosão do genoma desta espécie. A inferência filogenética por MSLA mostrou uma clara distinção dos grupos de cepas da América do Norte em relação às do Sul, sugerindo a ocorrência de mais eventos de recombinações genéticas nas cepas sul-americanas, provavelmente pela falta de isolamento geográfico. Assim, é possível que as cepas norte e sul-americanas sofreram divergência alopátrica e simpátrica, respectivamente. / The genus Xylella consists of a single species, Xylella fastidiosa, a Gram-negative and non-flagellated bacterium that colonizes the xylem of a diversity of cultivated and wild plants in several parts of the world. In some of these plants, this bacterium is considered causal agent of diseases such as the Citrus Variegated Cholorosis in orange trees, Pierce\'s Disease of grapevines and coffee leaf scald. Eleven different strains of X. fastidiosa isolated from different hosts had their genomes sequenced, including 9a5c and Temecula1 strains, respectively isolated from orange tree and grapevine. Analyses of these genomes indicate a reasonable variability in their sequences and showed several genes associated with pathogenicity and virulence mechanisms of this bacterium. In this work we describe the genome sequencing, assembly and annotation of the strains U24d and Fb7, isolated from orange trees, and 3124 isolated from coffee, which have, respectively, 2,681,334 bp, 2,733,974 bp and 2,748,594 bp. Of these, only strain U24d has a plasmid, identical to pXF51 from strain 9a5c. The genome of U24d strain is almost collinear to the genome of strain 9a5c while the genomes of strains Fb7 and 3124 had higher collinearity to Temecula1 strain. Among many changes found in the comparative analysis of these genomes, we highlight an on insertion in pilQ gene that was found in U24d strain genome. This mutation causes lack of type IV pilus with a consequent deficiency in twitching motility. Moreover orange trees infected with U24d strain showed localized symptoms near to the inoculation point. We verified that Fb7 strain does not form biofilm in vitro possibly due to the absence of expression of mrkD and pspA transcripts, which encode, respectively, a short pilus adhesin and a hemagglutinin-like adhesin. We postulate that these genes are not expressed due to a defect in the signaling pathway of DSF (Diffusible Signal Factor) reflecting a mutation on rpfC in the Fb7 genome. Similarly to other X. fastidiosa strains, the genomes of U24d, Fb7 and 3124 also showed high content of mobile genetic elements (MGE), which appear in larger numbers in South American strains. Pan genome studies of X. fastidiosa showed that this species has a open genome and that most of MGE genes correspond to accessory genes. The large number of MGE in X. fastidiosa may be related to the lack of a complete system CRISPR/cas, likely a result of erosion events of the genome of this species. The phylogenetic reconstruction by MLSA showed a clear distinction between groups of strains from North and South America, suggesting the occurrence of more recombination events in South American strains, probably due to lack of geographical isolation. Thus it is possible that North and South American strains underwent allopatric and sympatric divergence, respectively. Bacteriófago Bacteriophage Citrus variegated chlorosis Clorose Variegada dos Citros Comparative genomics Filogenia Genome sequencing genômica comparativa Pangenoma Pangenome Phylogeny sequenciamento de genomas Xylella fastidiosa Xylella fastidiosa

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