Global ETD Search

101	Characterisation of antibiotic resistance gene clusters and their mobility within a collection of multi-drug resistant Salmonella spp Liu, Xiulan. January 2009 (has links) Thesis (Ph.D.)--University of Wollongong, 2009. / Typescript. Includes bibliographical references: leaf 188-214.
102	Characterization of the OCT Plasmid-Encoded Mercury Resistance Genetic Locus in Pseudomonas putida Armbruster, Steven C. (Steven Christopher) 05 1900 (has links) A 17.1 Kb genetic element encoding for mercury resistance (OCT-Hg^r) was shown to translocate from its original location on the OCT plasmid to the resistance plasmid, RPl, in Pseudomonas putida. Analysis of RPl-Hg^r recombinant plasmids revealed that insertion of mercury resistance genes into RPl could occur at a variety of sites, with all recombinants having common EcoRI restriction fragments of 9.4, 3.8, 2.3, and 1.6 Kb, derived from the insertion. Hybridization analysis suggested the existence of extensive homology between this insertion and the prototypic mercury resistance transposon, Tn501, as well as the location of a similar merA sequence. Although the overall size was shown to be quite different from Tn501, striking physical similarities are shared between these two elements. mercury resistance plasmids Plasmids -- Genetics Mercury -- Toxicology -- Genetic aspects Pseudomonas putida
103	Towards a genetic system for the genus Sulfobacillus Joubert, Tertia Magdalena 03 1900 (has links) Thesis (MSc (Microbiology))--Stellenbosch University, 2008. / Members of the genus Sulfobacillus form an important part of the microbial consortia that are active in the biooxidation of sulphide ores in biomining processes, yet very little is known about these industrially important organisms. The study of sulfobacilli, and other biomining organisms, is hampered by the absence of effective gene cloning and inactivation systems. During this study, the groundwork was laid for the development of a genetic system for the genus Sulfobacillus. The plasmid diversity present in industrial and environmental isolates of sulfobacilli was assayed. Plasmids were plentiful in the assayed strains, providing the basis for development of cloning vectors for sulfobacilli. Plasmid DNA isolated from Sulfobacillus thermosulfidooxidans strain DSM 9293T was methylated at dam and dcm sites. Whether the methylase enzymes responsible for this methylation pattern form part of restriction-methylation systems or only play a regulatory role is unknown, but it does indicate the appropriate methylation state of DNA for the transformation of this strain. The DNA sequences of three plasmids originating from sulfobacilli were analysed and compared. There was no significant similarity between the three plasmid sequences, indicating diversity in plasmid genetic load and replication mechanisms. Plasmid pSulfBC1 was predicted to replicate via the rolling circle mechanism, while the replication mechanisms of pKara and pTHWX could not be predicted from sequence data. Two antibiotics, chloramphenicol and tetracyline, were found to be suitable for selection of Sulfobacillus transformants. E. coli – Sulfobacillus shuttle vectors were constructed using the Sulfobacillus plasmid, pKara, as the backbone with a Gram-positive chloramphenicol resistance marker and appropriate elements allowing replication in, and mobilization from, E. coli. These shuttle vectors were used in the evaluation of electroporation and conjugation as methods for the delivery of DNA to Sulfobacillus. Transformants of sulfobacilli could not be obtained by either transformation method, although some progress was made towards determining the optimal conditions for both methods. The most promising finding was that cells of E. coli and Sulfobacillus could be maintained on the same medium for a theoretically sufficient time to allow mating. It is likely that Sulfobacillus transconjugants can be obtained with the right combination of donor, mobilizable vector, selectable marker and treatment to neutralize restriction systems. Sulfobacillus -- Genetics Plasmids Dissertations -- Microbiology Theses -- Microbiology Microbiology
104	Characterisation of plasmid p31T1 isolated from Aeromonas Laubscher, Inge 12 1900 (has links) Thesis (MSc)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Plasmids are an integral part of the horizontal gene pool and, therefore, are the main vectors for the spread of antibiotic and heavy metal resistance genes in the environment. Functional and taxonomic characterization of novel plasmids is, therefore, central to our general understanding of plasmid biology and their contribution to microbial evolution. Two 14-kb mobilizable plasmids, p31T1 and p36T2, conferring resistance to tetracycline were isolated from the opportunistic fish pathogens Aeromonas sobria and Aeromonas hydrophila and were found to have indistinguishable restriction fragment length polymorphism (RFLP) patterns (Marx, MSc Thesis). DNA sequence analysis of the two isogenic plasmids (only p36T2 was sequenced) revealed the presence of 18 putative open reading frames (ORFs), of which the tetAR tetracycline resistance genes, associated with a truncated Tn1721, were the only ORFs with significant similarity to known sequences within the NCBI database. Putative functions were assigned to 10 of the ORFs based on their distant homology with proteins of known function. Six of the 18 ORFs, spanning 5.7-kb, were found to comprise the minimal region required for replication (minimal replicon) by means of deletion analysis using derivatives of p31T1. Of the six ORFs, ORF2 and ORF4 were found to be essential for plasmid replication. Inactivation of ORF3 resulted in an increase of plasmid copy number (PCN) from ~3 to ~7 plasmids per chromosome and a decrease in plasmid stability from ~80 % to 16 % over approximately 127 generations (7 days). Furthermore, by means of β-galactosidase promoter fusion assays it was shown that ORF3 autoregulated its own promoter. These results, therefore, suggested that although ORF3 was not essential for replication, it may be involved in plasmid copy number regulation and control. Host range analysis indicated that p31T1 was able to replicate in two other members of the γ-proteobacteria group (Escherichia coli and Pseudomonas putida) but was unable to do so in an α-proteobacterium strain, thus suggesting a limited host range. Furthermore, p31T1 was mobilized only at low frequencies (5.4 x 10-5 transconjugants per donor) by an IncP-1 conjugative system though it is possible that the mobilization system of these plasmids is adapted to function optimally with alternate conjugative systems. Given the unique PCN, stability, host range and mobilization characteristics determined for p31T1 and that no other plasmid replication and mobilization systems with significant sequence similarity to these plasmids have yet been identified, it is likely that these two plasmids are the first representative members of a new family of plasmids found within aquacultureassociated Aeromonas species and which are involved in the spread of tetracycline resistance. / AFRIKAANSE OPSOMMING: Plasmiede vorm ‘n integrale deel van die horisontale geen poel en vorm daarom die hoof vektore vir die verspreiding van antibiotika- en swaarmetaal-weerstandbiedende gene in die omgewing. Funksionele en taksonomiese karakterisering van nuwe plasmiede is belangrik in die begrip van plasmied biologie en hul bydrae tot mikrobiese evolusie. Twee 14-kb mobiliseerbare plasmiedes, p31T1 en p36T2, met tetrasiklien weerstandigheid was vanaf die opportunistiese vis patogene Aeromonas sobria en Aeromonas hydrophila geïsoleer en het identiese restriksie fragment lengte polimorfisme (RFLP) patrone. DNA volgorde analise van die twee isogeniese plasmiede (slegs die volgorde van p36T2 was bepaal) het die teenwoordigheid van 18 moontlike oop leesrame (OLR) getoon. Die tetAR tetrasiklien weerstandbiedende gene, wat met ‘n verkorte Tn1721 transposon geassosieerd is, was die enigste OLR wat beduidende volgorde ooreenkoms met bekende volgordes binne die NCBI databasis getoon het. Moontlike funksies was toegeken aan 10 van die OLRe en was gebasseer op vêrlangse homologie met proteïene met bekende funksies. Ses van die 18 OLRe strek oor ‘n 5.7- kb minimale replikon fragment wat benodig word vir replisering en is deur middel van delesie analises van p31T1 derivate gevind. Van hierdie ses OLRe, word OLR2 en OLR4 benodig vir plasmied replisering. Inaktivering van OLR3 het ‘n toename in plasmied kopiegetal (PKG) vanaf ~3 tot ~7 plasmiede per kromosoom en ‘n afname in stabiliteit vanaf ~80% tot 16% oor 127 generasies (7 dae) tot gevolg gehad. Verder kon daar deur middel van β-galaktosidase fusie analises getoon word dat OLR3 sy eie promotor outoreguleer. Hierdie resultate stel dus voor dat alhoewel OLR3 nie benodig was vir replikasie nie, mag dit dalk by plasmied kopiegetal regulering en beheer betrokke wees. Bakteriële gasheer analises het getoon dat p31T1 in 2 addisionele lede van die γ-proteobakterieë groep (Escherichia coli en Pseudomonas putida) kon repliseer, maar nie in ‘n α-proteobacterium nie. Verder kon p31T1 teen ‘n lae frekwensie (5.4 x 105) gemobiliseer word deur ‘n IncP-1 konjugasie sisteem, maar dit mag wees dat die mobilisering eerder optimaal kan plaasvind met ‘n alternatiewe konjugasie sisteem. Na aanleiding van die unieke PKG, stabiliteit, gasheer en mobilisering eienskappe wat vir p31T1 bepaal is en die feit dat geen ander replisering en mobilisering sisteme met noemenswaardige volgorde homologie tot hierdie plasmiede gevind kon word nie, blyk dit dat hierdie van die eerste lede van ‘n nuwe familie van plasmiede binne die akwakultuur-geassosieerde Aeromonas spesies is, wat betrokke is by die verspreiding van tetrasiklien weerstandbiedendheid. Plasmids -- Genetics Microbial biotechnology Aeromonas Theses -- Microbiology Dissertations -- Microbiology
105	CLONING OF BACILLUS SUBTILIS DNA: EXPRESSION IN B. SUBTILIS AND ESCHERICHIA COLI. ZUKOWSKI, MARK MICHAEL. January 1982 (has links) Bacillus subtilis DNA was cloned by ligating restriction endonuclease-generated fragments to plasmid vectors. The plasmid pUB110 was the vehicle in the construction of eight recombinant plasmids, pNM1 through pNM8. Each bears one or more EcoRI fragment(s) of B. subtilis chromosomal DNA. Recovery of the plasmids from host cells demonstrated that recombinant plasmids that bear some homology to the B, subtilis chromosome may be maintained outside of the chromosome in recombination-proficient hosts. The mean size of cloned fragments was 0.78 megadaltons (Mdal). The recombinant plasmid pNM1 interferes with the mechanism that blocks chromosomal recombination in B. subtilis cells that carry the recE4 mutation. Low-level chromosomal recombination at several loci was demonstrated when chromosomal DNA was accompanied by pNM1 in the transformation of recE4 recipient cells. The recombinant plasmid does not appear to code for recE gene products nor does it produce novel proteins when assayed in minicells of B. subtilis. An alternative approach to cloning B. subtilis DNA was successfully accomplished with the vector plasmid pHV33. The vector functions in both B. subtilis and E. coli hosts. B. subtilis chromosomal DNA was digested with Bg1II, then ligated to the unique BamHI site of pHV33. Ligation products were introduced into E. coli by transformation. Plasmid DNAs were isolated from transformants, pooled into several lots, then used to transform auxotrophic B. subtilis recipient cells. The procedure resulted in the construction of two new recombinant plasmids, pNM1055 and pNM1326. B. subtilis cells with the aroD120 mutation restored their ability to synthesize aromatic amino acids when pNM1055 was introduced. The same effect was observed in E. coli recipient cells that had the equivalent mutation. E. coli cells that carried pNM1326 produced granular colonies characteristic of the extraordinary filamentous growth exhibited by individual cells. The pNM1326 plasmid coded for a 16,000 dalton polypeptide produced in abundant quantities in E. coli hosts. A deletion derivative of pNM1326 did not produce the polypeptide, nor was filamentous growth of host cells exhibited. A plasmid-borne fragment of B. subtilis DNA affects cells growth and division of E. coli hosts. Recombinant DNA. Molecular cloning. Bacillus subtilis. Escherichia coli. Plasmids.
106	A Novel Mechanism for Site-Directed Mutagenesis of Large Catabolic Plasmids Using Natural Transformation Williamson, Phillip C. 08 1900 (has links) Natural transformation is the process by which cells take up DNA from the surrounding medium under physiological conditions, altering the genotype in a heritable fashion. This occurs without chemical or physical treatment of the cells. Certain Acinetobacter strains exhibit a strong tendency to incorporate homologous DNA into their chromosomes by natural transformation. Transformation in Acinetobacter exhibits several unique properties that indicate this system's superiority as a model for transformation studies or studies which benefit from the use of transformation as an experimental method of gene manipulation. Pseudomonas putida is the natural host of TOL plasmids, ranging between 50 kbp and 300 kbp in size and encoding genes for the catabolism of toluene, meta-toluate, and xylene. These very large, single-copy plasmids are difficult to isolate, manipulate, or modify in vitro. In this study, the TOL plasmid pDKR1 was introduced into Acinetobacter calcoaceticus strains and genetically engineered utilizing natural transformation as part of the process. Following engineering by transformation, the recombinant DNA molecule was returned to the native genetic background of the original host P. putida strain. Specific parameters for the successful manipulation of large plasmids by natural transformation in Acinetobacter were identified and are outlined. The effects of growth phase, total transforming DNA concentration, transforming DNA conformation, and gene dosage on transformation efficiency are presented. Addition of Acinetobacter plasmid DNA sequences to the manipulated constructs did not have an effect on transformation rates. Results suggest that a broadly applicable and efficient method to carry out site-directed genetic manipulations of large plasmids has been identified. The ability to easily reintroduce the recombinant DNA molecules back into the original host organism was maintained. Genetic engineering. Plasmids -- Genetics. Mutagenesis. Acintobactor calcoaceticas plasmid genetic engineering
107	Conjugative transfer and phylogeny of an antibiotic resistant haemophilus element, ICEHin1056 Robinson, Esther Rhiannon January 2012 (has links) Antibiotic resistance in bacteria is a growing threat to global health. Many of the genes responsible for resistance are carried on mobile genetic elements which can be transferred laterally between strains and species. The most important of these are conjugative and mobilisable elements including plasmids and integrating and conjugating elements, ICEs. Haemophi/us influenzae is an important human pathogen, which was first identified as carrying antibiotic resistance genes in the 1970s. Much of this resistance is encoded by ICEHin1056, which is present in H. influenzae strains worldwide. The aims of this study were to describe features of the biology of ICEHin1056, with particular reference to the genetic site and control mechanisms responsible for instigating conjugative transfer. The origin of transfer has been localised to a sequence on ICEHin1056 and an environmental stressor initiating conjugative transfer, oxidative stress, has been identified. In addition, detailed phylogenetic analysis has demonstrated ICEHin1056 to be part of a much larger family of mobile genetic elements, widely distributed in proteobacteria and carrying accessory genes responsible for survival in adverse environments, virulence and antibiotic resistance. The ICEs in the family have conserved homology of gene content and synteny of gene arrangement over deep evolutionary time, challenging the accepted paradigm of modular mosaicism of mobile genetic elements. A key event in increasing dissemination of the ICE, acquisition of a phage type integrase gene has also been identified. The findings presented provide significant insight into the behaviour of ICEs and may in future allow predictions about the spread of virulence factors and antibiotic resistance genes, with important implications for human and animal health. 615.7922
108	Biological evolution and the physics of growing microbial colonies Pastuszak, Jakub January 2016 (has links) In this thesis I investigate the role of spatial structure, cell-cell interactions and horizontal gene transfer on the genetic composition of growing microbial colonies. In the first part I study how the roughness of the growing layer of the colony depends on the shape of colony-forming cells. To study its impact I develop an off-lattice Eden-like model in which cells are represented as spherocylinders with a variable aspect ratio. I show that the roughness of the expansion front is not significantly affected by the shape of cells and that the dynamic scaling of growing front belongs to the KPZ universality class. Roughness is an important and easy to measure feature which affects the probability of fixation of genetic lineages in the colony. Another feature contributing to the genetic composition of a microbial community is horizontal gene transfer, which is investigated in the second part of this thesis. I develop an agent-based computational model of bacterial cells which grow, divide, and interact mechanically. I focus on plasmid conjugation, in which donors transfer a plasmid (a small, circular DNA molecule) to plasmid-free recipients. I show that bacteria in the expanding colony segregate into sectors of donors and acceptors. Donor sectors grow at the expense of acceptor sectors and that effect can be effectively described by coalescing random walkers that perform biased random walk on the colony expansion front. I use numerical and analytical methods to show that the plasmid eventually spreads to the whole colony given enough time, and I also show that this time is unrealistically long for experimentally determined conjugation rates and therefore real colonies are expected to have both acceptor and donor sectors. Furthermore, my simulations show that segregative plasmid loss at the moment of cell division can counteract the effect of conjugation and can lead to fixation of plasmid free cells. I also show that changes in nutrient concentration and the resultant change in roughness of the expansion front affect the rate of plasmid spread into population. Quantitative and qualitative results obtained in this section may serve as a tool to extract plasmid invasion rates from experimental data. In the last part of this thesis I investigate how the physical factors, such as finite strength of conjugative junctions, affect the conjugation process. I develop a computational model of plasmid transfer in which conjugative junctions are explicitly modelled as short, spring-like tubes that connect conjugating cells. My results show that factors such as junction creation rate and its strength can significantly affect the conjugation performance. I study different situations corresponding to different experimental scenarios (well-mixed colony on a filter paper, colliding colonies) and show that shear forces acting between cells can significantly lower the rate of plasmid transfer. My results can explain why conjugation occurs very rarely in some of these scenarios investigates in laboratory assays. 572.8
109	Determination of homology between the arsenic resistance plasmids R45 and R773 in Escherichia coli Clark, Joshua T. 01 January 1988 (has links) The resistance transfer factor R45 from Escherichia coli confers inducible arsenate and arsenite resistance in that bacterium. The genes for these resistances were cloned into the EcoRl - Sphl multiple cloning site of PGEM3 Blue vector (Promega) to produce a 4.9 kilobase plasmid, pJC1. This recombinant plasmid, pJC1, conferred IPTG induced resistance to arsenite and arsenate. In addition, pJCl was tested for homology with the E. coli plasmid R773, which encodes for arsenic resistance in that bacterium as well. Through DNA-DNA hybridization the arsenic resistance determinants of R45 and R773 were compared. Under stringent hybridization conditions, R45 demonstrated DNA sequence homology to the ArsB and Ars C genes of R773 but not to the ArsA gene of R773. Plasmids Arsenic R factors Escherichia coli Bacteria Biology
110	Characterisation of an 84 kb linear plasmid that encodes DDE cometabolism in Terrabacter sp. strain DDE-1 Shirley, Matt, n/a January 2006 (has links) DDT, an extremely widely used organochlorine pesticide, was banned in most developed countries more than 30 years ago. However, DDT residues, including 1,1-dichloro-2,2-bis(4-chlorophenyl)ethylene (DDE), still persist in the environment and have been identified as priority pollutants due to their toxicity and their ability to bioaccumulate and biomagnify in the food chain. In particular, DDE was long believed to be &quotenon-biodegradable&quote, however some microorganisms have now been isolated that are able to metabolise DDE in pure culture. Terrabacter sp. strain DDE-1 was enriched from a DDT-contaminated agricultural soil from the Canterbury plains and is able to metabolise DDE to 4-chlorobenzoic acid when induced with biphenyl. The primary objective of this study was to identify the gene(s) responsible for Terrabacter sp. strain DDE-1�s ability to metabolise DDE and, in particular, to investigate the hypothesis that DDE-1 degrades DDE cometabolically via a biphenyl degradation pathway. Catabolism of biphenyl by strain DDE-1 was demonstrated, and a biphenyl degradation (bph) gene cluster containing bphDA1A2A3A4BCST genes was identified. The bphDA1A2A3A4BC genes are predicted to encode a biphenyl degradation upper pathway for the degradation of biphenyl to benzoate and cis-2-hydroxypenta-2,4-dienoate and the bphST genes are predicted to encode a two-component signal transduction system involved in regulation of biphenyl catabolism. The bph gene cluster was found to be located on a linear plasmid, designated pBPH1. A plasmid-cured strain (MJ-2) was unable to catabolise both biphenyl and DDE, supporting the hypothesis that strain DDE-1 degrades DDE cometabolically via the biphenyl degradation pathway. Furthermore, preliminary evidence from DDE overlayer agar plate assays suggested that Pseudomonas aeruginosa carrying the strain DDE-1 bphA1A2A3A4BC genes is able to catabolise DDE when grown in the presence of biphenyl. A second objective of this study was to characterise pBPH1. The complete 84,054-bp sequence of the plasmid was determined. Annotation of the DNA sequence data revealed seventy-six ORFs predicted to encode proteins, four pseudogenes, and ten gene fragments. Putative functions were assigned to forty-two of the ORF and pseudogenes. Besides biphenyl catabolism, the major functional classes of the predicted proteins were transposition, regulation, heavy metal transport/resistance, and plasmid maintenance and replication. It was shown that pBPH1 has the terminal structural features of an actinomycete invertron, including terminal proteins and terminal inverted repeats (TIRs). This is the first report detailing the nucleotide sequence and characterisation of a (linear) plasmid from the genus Terrabacter. DDT (insecticide) persistent pollutants plasmids organochlorine compounds chlorohydrocarbons

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