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Advancements in Firefly Luciferase-Based Assays and Pyrosequencing TechnologyEriksson, Jonas January 2004 (has links)
Pyrosequencing is a new DNA sequencing method relying on thesequencing-by-synthesis principle and bioluminometric detectionof nucleotide incorporation events. The objective of thisthesis was improvement of the Pyrosequencing method byincreasing the thermal stability of firefly luciferase, and byintroducing an alternative DNA polymerase and a new nucleotideanalog. Furthermore, the development of a new bioluminescentassay is described for the detection of inorganicpyrophosphatase activity. The wild-type North American firefly(Photinus pyralis)luciferase is a heat-sensitiveenzyme, the catalytic activity of which is rapidly lost attemperatures over 30°C. Two strategies for increasing thethermostability of the enzyme are presented and discussed. Inthe first strategy, the solution thermodynamics of the systemis affected by osmolytes in such a way that heat-mediatedinactivation of the enzyme is prevented. In the secondstrategy, the enzyme is thermostabilized by mutagenesis. Bothstabilizing strategies can be utilized to allow bioluminometricassays to be performed at higher temperatures. For instance,both DNA polymerase and ATP sulfurylase activity could beanalyzed at 37°C. The osmolyte strategy was successfully employed forincreasing the reaction temperature for the Pyrosequencingmethod. By increasing the reaction temperature to 37°Cunspecific signals from primer-dimers and 3-end loopswere reduced. Furthermore, sequencing of a challenging templateat 37°C, which previously yielded poor, non-interpretablesequence signals at lower temperatures was now possible. Introduction of a new adenosine nucleotide analog,7-deaza-2-deoxyadenosine-5-triphosphate (c7dATP) reduced the inhibitory effect on apyraseobserved with the currently used analog,2-deoxyadenosine-5-O-(1-thiotriphosphate)(dATPαS). Sequencing of homopolymeric T-regions has previously beendifficult with the exonuclease-deficient form of the DNApolymerase I large (Klenow) fragment. By using the DNApolymerase from bacteriophage T7, known as Sequenase, templateswith homopolymeric T-regions were successfully sequenced.Furthermore, it was found that the strand displacement activityfor both polymerases was strongly assisted if the displacedstrand had a 5-overhang. In contrast, the stranddisplacement activity for both polymerases was inhibitedwithout an overhang, resulting in reduced sequencingperformance in double stranded regions. A firefly bioluminescent assay for the real-time detectionof inorganic pyrophosphatase in the hydrolytic direction wasalso developed. The assay is versatile and has a linearresponse in the range between 8 and 500 mU. Key words:bioluminescence, osmolytes, glycine betaine,thermostability, firefly luciferase, inorganic pyrophosphatase,inorganic pyrophosphate, Pyrosequencing technology, secondaryDNA-structures, Sequenase, Klenow-polymerase, reaction rates,temperature, c7dATP, dATPαS. / <p>QCR 20161027</p>
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Method development and applications of Pyrosequencing technologyGharizadeh, Baback January 2003 (has links)
The ability to determine nucleic acid sequences is one ofthe most important platforms for the detailed study ofbiological systems. Pyrosequencing technology is a relativelynovel DNA sequencing technique with multifaceted uniquecharacteristics, adjustable to different strategies, formatsand instrumentations. The aims of this thesis were to improvethe chemistry of the Pyrosequencing technique for increasedread-length, enhance the general sequence quality and improvethe sequencing performance for challenging templates. Improvedchemistry would enable Pyrosequencing technique to be used fornumerous applications with inherent advantages in accuracy,flexibility and parallel processing. Pyrosequencing technology, at its advent, was restricted tosequencing short stretches of DNA. The major limiting factorwas presence of an isomer of dATPaS, a substitute for thenatural dATP, which inhibited enzyme activity in thePyrosequencing chemistry. By removing this non-functionalnucleotide, we were able to achieve DNA read-lengths of up toone hundred bases, which has been a substantial accomplishmentfor performance of different applications. Furthermore, the useof a new polymerase, called Sequenase, has enabled sequencingof homopolymeric T-regions, which are challenging for thetraditional Klenow polymerase. Sequenase has markedly madepossible sequencing of such templates with synchronizedextension. The improved read-length and chemistry has enabledadditional applications, which were not possible previously.DNA sequencing is the gold standard method for microbial andvial typing. We have utilized Pyrosequencing technology foraccurate typing ofhuman papillomaviruses, and bacterial andfungal identification with promising results. Furthermore, DNA sequencing technologies are not capable oftyping of a sample harboring a multitude of species/types orunspecific amplification products. We have addressed theproblem of multiple infections/variants present in a clinicalsample by a new versatile method. The multiple sequencingprimer method is suited for detection and typing of samplesharboring different clinically important types/species(multiple infections) and unspecific amplifications, whicheliminates the need for nested PCR, stringent PCR conditionsand cloning. Furthermore, the method has proved to be usefulfor samples containing subdominant types/species, and sampleswith low PCR yield, which avoids reperforming unsuccessfulPCRs. We also introduce the sequence pattern recognition whenthere is a plurality of genotypes in the sample, whichfacilitates typing of more than one target DNA in the sample.Moreover, target specific sequencing primers could be easilytailored and adapted according to the desired applications orclinical settings based on regional prevalence ofmicroorganisms and viruses. Pyrosequencing technology has also been used forclone-checking by using preprogrammed nucleotide additionorder, EST sequencing and SNP analysis, yielding accurate andreliable results. <b>Keywords:</b>apyrase, bacterial identification, dATPaS, ESTsequencing, fungal identification, human papillomavirus (HPV),microbial and viral typing, multiple sequencing primer method,Pyrosequencing technology, Sequenase, single-strandedDNA-binding protein (SSB), SNP analysis
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Method development and applications of Pyrosequencing technologyGharizadeh, Baback January 2003 (has links)
<p>The ability to determine nucleic acid sequences is one ofthe most important platforms for the detailed study ofbiological systems. Pyrosequencing technology is a relativelynovel DNA sequencing technique with multifaceted uniquecharacteristics, adjustable to different strategies, formatsand instrumentations. The aims of this thesis were to improvethe chemistry of the Pyrosequencing technique for increasedread-length, enhance the general sequence quality and improvethe sequencing performance for challenging templates. Improvedchemistry would enable Pyrosequencing technique to be used fornumerous applications with inherent advantages in accuracy,flexibility and parallel processing.</p><p>Pyrosequencing technology, at its advent, was restricted tosequencing short stretches of DNA. The major limiting factorwas presence of an isomer of dATPaS, a substitute for thenatural dATP, which inhibited enzyme activity in thePyrosequencing chemistry. By removing this non-functionalnucleotide, we were able to achieve DNA read-lengths of up toone hundred bases, which has been a substantial accomplishmentfor performance of different applications. Furthermore, the useof a new polymerase, called Sequenase, has enabled sequencingof homopolymeric T-regions, which are challenging for thetraditional Klenow polymerase. Sequenase has markedly madepossible sequencing of such templates with synchronizedextension.</p><p>The improved read-length and chemistry has enabledadditional applications, which were not possible previously.DNA sequencing is the gold standard method for microbial andvial typing. We have utilized Pyrosequencing technology foraccurate typing ofhuman papillomaviruses, and bacterial andfungal identification with promising results.</p><p>Furthermore, DNA sequencing technologies are not capable oftyping of a sample harboring a multitude of species/types orunspecific amplification products. We have addressed theproblem of multiple infections/variants present in a clinicalsample by a new versatile method. The multiple sequencingprimer method is suited for detection and typing of samplesharboring different clinically important types/species(multiple infections) and unspecific amplifications, whicheliminates the need for nested PCR, stringent PCR conditionsand cloning. Furthermore, the method has proved to be usefulfor samples containing subdominant types/species, and sampleswith low PCR yield, which avoids reperforming unsuccessfulPCRs. We also introduce the sequence pattern recognition whenthere is a plurality of genotypes in the sample, whichfacilitates typing of more than one target DNA in the sample.Moreover, target specific sequencing primers could be easilytailored and adapted according to the desired applications orclinical settings based on regional prevalence ofmicroorganisms and viruses.</p><p>Pyrosequencing technology has also been used forclone-checking by using preprogrammed nucleotide additionorder, EST sequencing and SNP analysis, yielding accurate andreliable results.</p><p><b>Keywords:</b>apyrase, bacterial identification, dATPaS, ESTsequencing, fungal identification, human papillomavirus (HPV),microbial and viral typing, multiple sequencing primer method,Pyrosequencing technology, Sequenase, single-strandedDNA-binding protein (SSB), SNP analysis</p>
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Advancements in Firefly Luciferase-Based Assays and Pyrosequencing TechnologyEriksson, Jonas January 2004 (has links)
<p>Pyrosequencing is a new DNA sequencing method relying on thesequencing-by-synthesis principle and bioluminometric detectionof nucleotide incorporation events. The objective of thisthesis was improvement of the Pyrosequencing method byincreasing the thermal stability of firefly luciferase, and byintroducing an alternative DNA polymerase and a new nucleotideanalog. Furthermore, the development of a new bioluminescentassay is described for the detection of inorganicpyrophosphatase activity.</p><p>The wild-type North American firefly<i>(Photinus pyralis)</i>luciferase is a heat-sensitiveenzyme, the catalytic activity of which is rapidly lost attemperatures over 30°C. Two strategies for increasing thethermostability of the enzyme are presented and discussed. Inthe first strategy, the solution thermodynamics of the systemis affected by osmolytes in such a way that heat-mediatedinactivation of the enzyme is prevented. In the secondstrategy, the enzyme is thermostabilized by mutagenesis. Bothstabilizing strategies can be utilized to allow bioluminometricassays to be performed at higher temperatures. For instance,both DNA polymerase and ATP sulfurylase activity could beanalyzed at 37°C.</p><p>The osmolyte strategy was successfully employed forincreasing the reaction temperature for the Pyrosequencingmethod. By increasing the reaction temperature to 37°Cunspecific signals from primer-dimers and 3-end loopswere reduced. Furthermore, sequencing of a challenging templateat 37°C, which previously yielded poor, non-interpretablesequence signals at lower temperatures was now possible.</p><p>Introduction of a new adenosine nucleotide analog,7-deaza-2-deoxyadenosine-5-triphosphate (c<sup>7</sup>dATP) reduced the inhibitory effect on apyraseobserved with the currently used analog,2-deoxyadenosine-5-O-(1-thiotriphosphate)(dATPαS).</p><p>Sequencing of homopolymeric T-regions has previously beendifficult with the exonuclease-deficient form of the DNApolymerase I large (Klenow) fragment. By using the DNApolymerase from bacteriophage T7, known as Sequenase, templateswith homopolymeric T-regions were successfully sequenced.Furthermore, it was found that the strand displacement activityfor both polymerases was strongly assisted if the displacedstrand had a 5-overhang. In contrast, the stranddisplacement activity for both polymerases was inhibitedwithout an overhang, resulting in reduced sequencingperformance in double stranded regions.</p><p>A firefly bioluminescent assay for the real-time detectionof inorganic pyrophosphatase in the hydrolytic direction wasalso developed. The assay is versatile and has a linearresponse in the range between 8 and 500 mU.</p><p><b>Key words:</b>bioluminescence, osmolytes, glycine betaine,thermostability, firefly luciferase, inorganic pyrophosphatase,inorganic pyrophosphate, Pyrosequencing technology, secondaryDNA-structures, Sequenase, Klenow-polymerase, reaction rates,temperature, c<sup>7</sup>dATP, dATPαS.</p>
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