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Characterization of psychrophilic alleles of essential genes as means of generating temperature-sensitive strains of mesophilic organismsPankowski, Jaroslaw 13 April 2016 (has links)
Essential genes are involved in control of the basic metabolism of their host. These genes encode elements involved is such crucial processes as DNA replication, transcription, translation or biosynthesis of important molecules. What makes essential genes unique is the fact that they cannot be lost from the genome. If any of them becomes inactivated it would result in inevitable death of an organism. Because of their role they can be efficiently used to control the survival of genetically modified organisms. Specific regulatory mechanisms can be applied to modulate the activity of essential genes, which prevents an organism from growing at determined conditions. Such mechanisms are called “kill switches” and have been developed in recent years as a response to significant development in the field of molecular biology.
Proteins encoded by psychrophilic organisms are characterized by decreased resistance to thermal denaturation. This is believed to be a result of adaptation to low-temperature environment, where mutations that destabilize the protein structure are not selected against. For these reasons they often cannot perform their functions at moderate temperatures, which are typical for mesophilic organisms. At the same time psychrophilic proteins do not display any inhibition at permissive conditions.
Use of psychrophilic alleles of essential genes has been proposed as a method of rendering modified organisms incapable of surviving at elevated temperatures. This allows generation of attenuated strains of pathogenic bacteria or generally safe versions of laboratory organisms. A temperature-sensitive organism can be created by substituting a single essential gene in mesophilic organism with its psychrophilic homologue. This can be facilitated by using the host’s native recombination system or through the use of plasmid based allele shuffling mechanisms.
The objective of this work was to analyze a number of psychrophilic alleles of various essential genes for their ability to cause temperature-sensitive phenotype in mesophilic bacterium Francisella novicida. The special attention has been placed on investigating psychrophilic alleles of bacterial DNA ligase. Furthermore a selected psychrophilic strain has been characterized as a potential source of multiple temperature-sensitive alleles of essential genes. Finally the secondary focus was to develop a simple and robust mechanism allowing efficient exchange of alleles of essential genes in the mesophilic host. / Graduate
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Modulation of Base Excision Repair by NucleosomesOdell, Ian 18 November 2010 (has links)
DNA in eukaryotes is packaged into nucleosomes, which present steric impediments to many of the factors and enzymes that act on DNA, including DNA repair enzymes. Within the nucleosome, DNA remains vulnerable to oxidative damage that can result from normal cellular metabolism, ionizing radiation, and various chemical agents. Oxidatively damaged DNA is repaired in a stepwise fashion via the base excision repair (BER) pathway. Other DNA repair pathways, including Nucleotide Excision Repair (NER), Mismatch Repair (MMR), Homologous Recombination (HR), and Non-homologous End-Joining (NHEJ) are all thought to require nucleosome remodeling or disruption. In contrast, it was reported that the first step of BER does not require or induce nucleosome disruption. For example, the human DNA glycosylase hNTH1 (human Endonuclease III) was discovered to excise thymine glycol lesions from nucleosomes without nucleosome disruption, and could excise optimally oriented lesions with an efficiency approaching that seen for naked DNA (Prasad, Wallace, and Pederson 2007). To determine if the properties of hNTH1 are shared by other human DNA glycosylases, we compared hNTH1 with NEIL1, a human DNA glycoylase that also excises thymine glycol from DNA, with respect to their activities on nucleosome substrates. We found that the cellular concentrations and apparent kcat/KM ratios for hNTH1 and NEIL1 are similar. However, NEIL1 and hNTH1 differ in that NEIL1 binds undamaged DNA far more avidly than hNTH1. After adjustment for non-specific DNA binding, hNTH1 and NEIL1 proved to have similar intrinsic activities towards nucleosome substrates. We next wanted to examine the effects of nucleosomes on enzymes that catalyze the remaining steps in BER. We therefore assembled the entire four-step BER reaction with model, lesion-containing nucleosomes. The rates of substrate processing during the first three steps in BER, catalyzed by a DNA glycosylase, AP endonuclease, and DNA Polymerase Pol), varied with the helical orientation of the substrate relative to the underlying histone octamer. In contrast, the rate of action by DNA Ligase III- (in association with XRCC1) was independent of lesion orientation. These results are consistent with structural studies of BER enzymes and the previously proposed DNA unwrapping model for how BER enzymes gain access to lesions in nucleosomes (Prasad, Wallace, and Pederson 2007). During these investigations, we also discovered a synergistic interaction between Pol and Ligase III- complexed with XRCC1 that enhances the repair of lesions in nucleosomes. Together, our results support the hypothesis that DNA glycosylases have evolved to function in specific cellular environments (e.g. NEIL1 may function exclusively during DNA replication), but also possess DNA binding motifs and mechanisms of substrate recognition that impart a similar intrinsic activity on nucleosomes. In addition to hNTH1 and NEIL1, we have discovered that lesion orientation is also an important factor to the activities of APE and Pol and that the complete BER reaction can occur without requiring or inducing nucleosome disruption. Finally, protein-protein interactions between XRCC1 and Pol may be important for the efficient in vivo repair of lesions in nucleosomes.
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Mismatch ligation during non-homologous end joining pathway: kinetic characterization of human DNA ligase IV/XRCC4 complexWang, Yu 10 July 2007 (has links)
No description available.
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Temperature sensitive Mycobacterium tuberculosis as a potential vaccine candidatePinto, Crystal Tina 29 June 2015 (has links)
Mycobacterium tuberculosis remains one of the most common worldwide causes of illness and death due to an infectious disease. The emergence of multiple and extreme-drug resistant strains has increased the need to find an effective vaccine for tuberculosis. The goal of our research group is to engineer a temperature-sensitive (TS) M. tuberculosis strain that can be used as a tool in vaccine development. One approach to create TS M. tuberculosis involves the integration of the essential gene ligA encoding a TS NAD+ dependent DNA ligase, which was taken from the psychrophilic organism Pseudoalteromonas haloplanktis. The integration and functioning of ligA was demonstrated in the fast-growing organism Mycobacterium smegmatis. This strain had a TS phenotype with growth limited to below 37°C. The strain was found to have a stable TS phenotype and did not mutate to a temperature-resistant form at a detectable level. Following experiments with the fast growing M. smegmatis, the integration of the ligA gene was attempted in slow-growing M. tuberculosis. Merodiploids of M. tuberculosis containing both the psychrophilic and the WT ligA gene in its chromosome were obtained.
The second approach used for the development of TS M. tuberculosis was the directed evolution of native M. tuberculosis essential genes. An advantage of this approach is that the gene encoding the essential protein will resemble the native M. tuberculosis gene and thus will closely match the native transcriptional and translational rates. A system to screen and select for TS essential genes engineered by directed evolution was designed, where the essential gene on the chromosome of E. coli was knocked out and this gene was supplied on a conditionally replicating plasmid. As a first step in developing this directed evolution approach, a family of conditionally replicating plasmids were created and tested in an essential gene knock-out strain of E. coli. / Graduate
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Characterisation of a DNA ligase from an Antarctic metagenomic libraryBooyse, Dean January 2011 (has links)
<p>A metagenomic gene library prepared from soil found beneath a mummified seal carcass in the Miers Valley, Antarctica, suggests an environment rich in uncharacterised biodiversity including enzymes with possible application to industrial processes. A sequence based gene mining investigation was performed on a clone, which archives a metagenomic sequence from this environment. The sequence was annotated using de novo bioinformatics and molecular biology techniques. A predicted NAD+-dependent DNA ligase, ligDB1 was selected for further characterisation. LigDB1 encodes a gene product that contains all the sequence features of a functional ligase. The protein was overexpressed in a heterologous E. coli host and purified to homogeneity. LigDB1 did not exhibit nick sealing activity, but was able to perform AMP-dependent DNA relaxation in the presence of high concentrations of enzyme. DNA modifying enzymes from cold environments perform optimally at low temperatures and may be of use as molecular tools in biotechnology. Complete characterisation of this enzyme is subject to further investigations.</p>
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Characterisation of a DNA ligase from an Antarctic metagenomic libraryBooyse, Dean January 2011 (has links)
<p>A metagenomic gene library prepared from soil found beneath a mummified seal carcass in the Miers Valley, Antarctica, suggests an environment rich in uncharacterised biodiversity including enzymes with possible application to industrial processes. A sequence based gene mining investigation was performed on a clone, which archives a metagenomic sequence from this environment. The sequence was annotated using de novo bioinformatics and molecular biology techniques. A predicted NAD+-dependent DNA ligase, ligDB1 was selected for further characterisation. LigDB1 encodes a gene product that contains all the sequence features of a functional ligase. The protein was overexpressed in a heterologous E. coli host and purified to homogeneity. LigDB1 did not exhibit nick sealing activity, but was able to perform AMP-dependent DNA relaxation in the presence of high concentrations of enzyme. DNA modifying enzymes from cold environments perform optimally at low temperatures and may be of use as molecular tools in biotechnology. Complete characterisation of this enzyme is subject to further investigations.</p>
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INSIGHTS INTO ENZYMATIC MANIPULATIONS OF NUCLEIC ACIDSAlexander, Rashada Corine 01 January 2005 (has links)
This dissertation details three studies dealing with the manipulation of nucleicacids. In the first investigation, each of the four natural nucleobases were analyzed for theability to serve as a universal template at the ligation junction of a T4 DNA ligasereaction. This resulted in the first instance of sequence-independent ligation catalyzed byany DNA ligase. Although all of the nucleobases display universal templatingcapabilities, thymidine and guanosine provided the most effective results. In addition,lowered MgCl2 and ATP concentrations, as well as the inclusion of DMSO, also aided inthe sequence-independent ligation reported here. In the course of these studies, currentmethods of removing urea from denaturing-gel purified nucleic acids provedcumbersome. Therefore, in the second study simple butanol extraction was examined as ameans to eliminate urea from nucleic acid solutions. Stepwise butanol extraction was themost effective approach to solving this problem and provided a much needed techniquefor nucleic acid purification. This type of extraction also does not result in significantlosses of nucleic acid sample. The third study exploits the molecular recognition andcatalytic properties inherent in an autocatalytic group I intron to develop a ribozyme thatcan replace the 5' end of an RNA substrate with a different RNA. This 5' replacementsplicing reaction can potentially repair mutations on the 5' ends of RNA transcripts thatlead to a variety of genetic mutations. The model system was a common mutation in asmall model mimic of the k-ras gene in vitro, which predisposes individuals to lungcancer. This 5' replacement splicing reaction occurred in vitro using this small modelsystem; the reaction was also enhanced by the alteration of the molecular interactionsinvolved. The results and implications of each of these studies are detailed in thisdissertation.
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Characterisation of a DNA ligase from an Antarctic metagenomic libraryBooyse, Dean January 2011 (has links)
A metagenomic gene library prepared from soil found beneath a mummified seal carcass in the Miers Valley, Antarctica, suggests an environment rich in uncharacterised biodiversity including enzymes with possible application to industrial processes. A sequence based gene mining investigation was performed on a clone, which archives a metagenomic sequence from this environment. The sequence was annotated using de novo bioinformatics and molecular biology techniques. A predicted NAD+-dependent DNA ligase, ligDB1 was selected for further characterisation. LigDB1 encodes a gene product that contains all the sequence features of a functional ligase. The protein was overexpressed in a heterologous E. coli host and purified to homogeneity. LigDB1 did not exhibit nick sealing activity, but was able to perform AMP-dependent DNA relaxation in the presence of high concentrations of enzyme. DNA modifying enzymes from cold environments perform optimally at low temperatures and may be of use as molecular tools in biotechnology. Complete characterisation of this enzyme is subject to further investigations. / Magister Scientiae - MSc
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Characterisation of a DNA ligase from an Antarctic metagenomic libraryBooysen, Dean January 2011 (has links)
A metagenomic gene library prepared from soil found beneath a mummified seal carcass in the Miers Valley, Antarctica, suggests an environment rich in uncharacterised biodiversity including enzymes with possible application to industrial processes. A sequence based gene mining investigation was performed on a clone, which archives a metagenomic sequence from this environment. The sequence was annotated using de novo bioinformatics and molecular biology techniques. A predicted NAD+-dependent DNA ligase, ligDB1 was selected for further characterisation. LigDB1 encodes a gene product that contains all the
sequence features of a functional ligase. The protein was overexpressed in a heterologous E.coli host and purified to homogeneity. LigDB1 did not exhibit nick sealing activity, but was able to perform AMP-dependent DNA relaxation in the presence of high concentrations of enzyme. DNA modifying enzymes from cold environments perform optimally at low temperatures and may be of use as molecular tools in biotechnology. Complete characterisation of this enzyme is subject to further investigations. / Magister Scientiae - MSc
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Characterisation of a DNA ligase from an Antarctic metagenomic libraryBooysen, Dean January 2011 (has links)
>Magister Scientiae - MSc / A metagenomic gene library prepared from soil found beneath a mummified seal carcass in the Miers Valley, Antarctica, suggests an environment rich in uncharacterised biodiversity including enzymes with possible application to industrial processes. A sequence based gene mining investigation was performed on a clone, which archives a metagenomic sequence from this environment. The sequence was annotated using de novo bioinformatics and molecular biology techniques. A predicted NAD+-dependent DNA ligase, ligDB1 was selected for further characterisation. LigDB1 encodes a gene product that contains all the sequence features of a functional ligase. The protein was overexpressed in a heterologous E. coli host and purified to homogeneity. LigDB1 did not exhibit nick sealing activity, but was able to perform AMP-dependent DNA relaxation in the presence of high concentrations of enzyme. DNA modifying enzymes from cold environments perform optimally at low temperatures and may be of use as molecular tools in biotechnology. Complete characterisation of this enzyme is subject to further investigations
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