Protein based approaches for further development of the pyrosequencing technology platform

Ehn, Maria

January 2003

The innovation of DNA analysis techniques has enabled arevolution in the field of molecular biology. In the 70’s,first technologies for sequence determination of DNA wereinvented and these techniques enormously increased thepossibilities of genetic research. A large proportion ofmethods for DNA sequencing is based on enzymatic DNA synthesiswith chain termination followed by electrophoretic separationand detection. However, alternative approaches have beendeveloped and one example of this is the pyrosequencingtechnology, which a four-enzyme DNA sequencing method based onreal-time monitoring of DNA synthesis. Currently, the method is limited to analysis of short DNAsequences and therefore it has primarily been used for mutationdetection and single-nucleotide polymorphism analysis. In orderto expand the use of the pyrosequencing technology, the readlength obtained in the methods needs to be improved. However,it was previously shown that the data quality in pyrosequencingtechnology could be significantly increased by addition ofEscherichia coli single-stranded DNAbinding protein, SSB, tothe sequencing reaction. Since little was known about themechanism of this enhancement, we performed a systematic effortto analyse the effect of SSB on 103 clones randomly selectedfrom a cDNA library. We investigated the effect of SSB on theobtained read length in pyrosequencing and identified thecauses of low quality sequences. Moreover, the effciency ofprimer annealing and SSB binding for individual cDNA clones wasinvestigated by use of real-time biosensor analysis. Resultsfrom these experiments show that templates with highperformance in pyrosequencing without SSB possess effcientprimer annealing and low SSB affnity. To minimise the cost of the pyrosequencing system, effcientand scaleable procedures for production and isolation of theprotein components are required. Therefore, protocol foreffcient expression in E.coliand rapid isolation of native SSB was developed.Moreover, by use of a gene fusion strategy, Klenow polymerasewas produced in fusion with the Zbasic domain at high levels inE. coli. This highly charged protein handle enables selectiveand effcient ion exchange purification at physiological pH.Furthermore, active Apyrase was expressed in Methyltropic yeastPichia pastoris and purified by two chromatographic steps. Since pyrosequencing analysis mainly is performed in a96-sample plate format, an increase in sample capacity would bevery beneficial. One approach to achieve this would be to usemicromachined filter chamber arrays where nano-liter samplescan be monitored in real-time. However, to enable accuratepyrosequencing analysis of parallel samples, the produced lightshould preferable be docked to the correct DNA template.Therefore, two different gene fusion strategies were utilisedbased on directed immobilisation of the light-harvesting enzymeLuciferase on the DNA molecules. The thermostable variant ofthe enzyme was genetically fused to a DNA binding protein(either SSB or Klenow) and the Zbasic purification handle, which could beselectively removed by protease cleavage. A protocol wasdeveloped for effcient expression in E.coliand purification by Ion Exchange Chromatography.The proteins were analysed by complete extension of DNAtemplates immobilised on magnetic beadspyrosequencing monitoredby pyrosequencing chemistry. Results from these experimentsshow that the proteins bound selectively to the immobilised DNAand that their enzymatic domains were active. In summary, the work presented in this thesis pinpointsfeatures in the pyrosequencing technology that needs to befurther developed. Moreover, various protein-based strategiesare presented in order to overcome these limitations. <b>Keywords:</b>pyrosequencing, SSB, Zbasic, Klenow, Apyrase, expression, purification,Biacore, DNA template length, Luciferase, affnity, gene fusion,immobilisation.

pyrosenquencing

ssb

zbasic

klenow

apyrase

expression

purification

Protein based approaches for further development of the pyrosequencing technology platform

Ehn, Maria

January 2003

<p>The innovation of DNA analysis techniques has enabled arevolution in the field of molecular biology. In the 70’s,first technologies for sequence determination of DNA wereinvented and these techniques enormously increased thepossibilities of genetic research. A large proportion ofmethods for DNA sequencing is based on enzymatic DNA synthesiswith chain termination followed by electrophoretic separationand detection. However, alternative approaches have beendeveloped and one example of this is the pyrosequencingtechnology, which a four-enzyme DNA sequencing method based onreal-time monitoring of DNA synthesis.</p><p>Currently, the method is limited to analysis of short DNAsequences and therefore it has primarily been used for mutationdetection and single-nucleotide polymorphism analysis. In orderto expand the use of the pyrosequencing technology, the readlength obtained in the methods needs to be improved. However,it was previously shown that the data quality in pyrosequencingtechnology could be significantly increased by addition ofEscherichia coli single-stranded DNAbinding protein, SSB, tothe sequencing reaction. Since little was known about themechanism of this enhancement, we performed a systematic effortto analyse the effect of SSB on 103 clones randomly selectedfrom a cDNA library. We investigated the effect of SSB on theobtained read length in pyrosequencing and identified thecauses of low quality sequences. Moreover, the effciency ofprimer annealing and SSB binding for individual cDNA clones wasinvestigated by use of real-time biosensor analysis. Resultsfrom these experiments show that templates with highperformance in pyrosequencing without SSB possess effcientprimer annealing and low SSB affnity.</p><p>To minimise the cost of the pyrosequencing system, effcientand scaleable procedures for production and isolation of theprotein components are required. Therefore, protocol foreffcient expression in E.<i>coli</i>and rapid isolation of native SSB was developed.Moreover, by use of a gene fusion strategy, Klenow polymerasewas produced in fusion with the Zbasic domain at high levels inE. coli. This highly charged protein handle enables selectiveand effcient ion exchange purification at physiological pH.Furthermore, active Apyrase was expressed in Methyltropic yeastPichia pastoris and purified by two chromatographic steps.</p><p>Since pyrosequencing analysis mainly is performed in a96-sample plate format, an increase in sample capacity would bevery beneficial. One approach to achieve this would be to usemicromachined filter chamber arrays where nano-liter samplescan be monitored in real-time. However, to enable accuratepyrosequencing analysis of parallel samples, the produced lightshould preferable be docked to the correct DNA template.Therefore, two different gene fusion strategies were utilisedbased on directed immobilisation of the light-harvesting enzymeLuciferase on the DNA molecules. The thermostable variant ofthe enzyme was genetically fused to a DNA binding protein(either SSB or Klenow) and the Z_basic purification handle, which could beselectively removed by protease cleavage. A protocol wasdeveloped for effcient expression in E.<i>coli</i>and purification by Ion Exchange Chromatography.The proteins were analysed by complete extension of DNAtemplates immobilised on magnetic beadspyrosequencing monitoredby pyrosequencing chemistry. Results from these experimentsshow that the proteins bound selectively to the immobilised DNAand that their enzymatic domains were active.</p><p>In summary, the work presented in this thesis pinpointsfeatures in the pyrosequencing technology that needs to befurther developed. Moreover, various protein-based strategiesare presented in order to overcome these limitations.</p><p><b>Keywords:</b>pyrosequencing, SSB, Z_basic, Klenow, Apyrase, expression, purification,Biacore, DNA template length, Luciferase, affnity, gene fusion,immobilisation.</p>

pyrosenquencing

ssb

zbasic

klenow

apyrase

expression

purification

Protein-Nucleic Acid Interactions in Nuclease and Polymerases

rob, abdur

05 May 2011

DNA polymerase binds to the double stranded DNA and extends the primer strand by adding deoxyribonucletide to the 3’-end. Several reactions in the polymerase active site have been reported by Kornberg in addition to the polymerization. We observed DNA polymerase I can act as a pyrophosphatase and hydrolyze deoxyribonucletide. In performing the pyrophosphatase activity, DNA polymerase I requires to interact with RNA. RNA in general, was found to activate the DNA polymerase I as pyrophosphatase. This hydrolysis causes depletion of dNTP and inhibits DNA polymeration synthesis in vitro. In this RNA-dependent catalysis, DNA polymerase I catalyzes only dNTP but not rNTP. We have also observed that many other DNA polymerases have this type of the RNA-dependent pyrophosphatase activity. Our experimental data suggest that the exonuclease active sites most likely play the critical role in this RNA-dependent dNTP hydrolysis, which might have a broader impact on biological systems. On the basis of the crystal structure of a ternary complex of RNase H (Bacillus halodurans), DNA, and RNA, we have introduced the selenium modification at the 6-position of guanine (G) by replacing the oxygen (SeG). The SeG has been incorporated into DNA (6 nt. - 6 nucleotides) by solid phase synthesis. The crystal structure and biochemical studies with the modified SeG-DNA indicate that the SeDNA can base-pair with the RNA substrate and serve as a template for the RNA hydrolysis. In the crystal structure, it has been observed that the selenium introduction causes shifting (or unwinding) of the G-C base pair by 0.3 Å. Furthermore, the Se-modification can significately enhance the phosphate backbone cleavage (over 1000 fold) of the RNA substrate, although the modifications are remotely located on the DNA bases. This enhancement in the catalytic step is probably attributed to the unwinding of the local duplex, which shifts scissile phosphate bond towards the enzyme active site. Our structural, kinetic and thermodynamic investigations suggest a novel mechanism of RNase H catalysis, which was revealed by the atom-specific selenium modification.

DNA polymerase

Klenow fragment

Selenium-modified DNA

RNA

Phasing and crystallization

Template

Chemistry

Effects of fusion tags on protein partitioning In aqueous two-phase systems and use in primary protein recovery

Hassinen, Cynthia

January 2002

<p>The two techniques aqueoustwo-phase partitioning and expanded bed adsorption that bothare suitable for primary protein recovery were studied. Most ofthe work was focused on partition in aqueous two-phase systemsand in particular on the possibility to effect the partitionbehaviour by fusion of short peptide tags or protein domains tothe target protein.</p><p>The partitioning of fusionproteins between different variants of the domain tag Z and thenaturally occurring protein DNA Klenow polymerase were studiedin Breox/Reppal aqueous two-phase systems. Most studies wereperformed with cell homogenate. The Breox/Reppal system was infocus because if the fusion protein can be partitioned to theBreox-rich top phase the next step can be a thermoseparatingaqueous two-phase system. When the Breox phase is heated to50°C it switches from a one-phase system to a two-phasesystem resulting in an almost pure water rich top phase andhighly concentrated Breox-rich bottom phase. The Breox can thenbe reused and the protein recovered from the water phase. TheZ-domain was genetically modified in different ways to Z_basic1, Z_acid2and Z_trp12and fused to the Klenow protein to try toenhance partitioning to the Breox-rich phase. From theexperiments it was not possible to observe any effects on thepartition behaviour irrespectively of tested properties of thedomain tag. Despite the absence of domain tag effects highK-values, i.e. partition to the Breox-rich top phase, wereobserved in the Breox/Reppal system. However, the proteinK-values seemed to be rather sensitive to the cell homogenateload and showed a tendency to decrease with increased cellhomogenate load. Also increased phosphate concentration reducedthe K-values. The partitioning of cell debris also seemed todependent on the cell homogenate load. At higher homogenateload (<=20g DW/L) clear Breox-rich top phases were observedwith the cell debris collected in Reppal-rich bottomphases.</p><p>Two different tetrapeptides,AlaTrpTrpPro and AlaIleIlePro were inserted near the C-terminusof the protein ZZT0. The Trp-rich peptide unit stronglyincreased both the partitioning of ZZT0 into the poly(ethyleneglycol) (PEG)-rich phase in a PEG/potassium phosphate aqueoustwo-phase system and its retention on PEG and propylhydrophobic interaction chromatographic columns with potassiumphosphate as eluent in isocratic systems. Both the partitioningand the retention increased with increasing number of Trp-richpeptide units inserted into ZZT0. Insertion of Ile-richtetrapeptide units affected the partitioning and retention to amuch lesser extent. Partition and modelling data also indicateda folding of inserted Trp and Ile tetrapeptide units, probablyto minimise their water contact. It was also investigated howto predict the partitioning of proteins in isoelectricPEG/phosphate aqueous two-phase systems.</p><p>The capture ofß-galactosidase from<i>E. coli</i>cell homogentate (50g DW/L) by metal chelatexpanded bed adsorption was studied. These experiments showedthat capture, with a certain degree of selectivity, andclarification of ß-galactosidase could be achieved from acell homogenate. However, a rather low recovery of about 35 %was obtained at a capacity of 0.25mg/mL of gel. Thus, severalparameters remain to be optimised like the load buffercomposition and the cell homogenate load.</p><p><b>Keywords:</b><i>E. coli</i>, aqueous two-phase systems, fusion proteins,hydrophobic interaction chromatography, expanded bedadsorption, ß-galactosidase, Klenow polymerase, Z-domain,peptide tags</p>

E. coli

Aqueous two-phase systems

Fusion proteins

Hydrophobic interaction chromatography

Expanded bed adsorption

Beta-galactosidase

Klenow polymerase

Z-domain

Peptide tags

Advancements in Firefly Luciferase-Based Assays and Pyrosequencing Technology

Eriksson, Jonas

January 2004

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>

bioluminescence

osmolytes

glycine betaine

thermostability

firefly luciferase

inorganic pyrophosphatase

inorganic pyrophosphate

Pyrosequencing technology

secondary DNA-structures

Sequenase

Klenow-polymerase

reaction rates

temperature

Synthesis and Enzymatic Studies of Selenium Derivatized Nucleosides, Nucleotides and Nucleic Acids

Caton-Williams, Julianne Marie

14 June 2009

Nucleoside 5-triphosphates are the building blocks to synthesis of nucleic acids. Nucleic acids (RNA and DNA) participate in many important biological functions in living systems, including genetic information storage, gene expression, and catalysis. Nucleoside 5- triphosphates have many important therapeutic and diagnostic applications. To understand how these triphosphates are utilized in living systems, numerous synthetic mimics have been prepared and used as active metabolites of certain drugs and molecular probes. Over the years, nucleic acids have been modified at the nucleobase, sugar moiety and phosphate backbone with the aim of understanding their structures and functions. We have site-specifically replaced selected oxygen atoms of nucleosides and nucleotides with selenium atom in order to enzymatically synthesize selenium-derivatized DNAs for obtaining insights into the DNA flexibility, duplex recognition and stability. Although triphosphates have important biological and medicinal significance, they are however, very difficult to synthesize and isolate in high purity and yield. There are many approaches to the synthesis of nucleoside 5-triphosphates, but there is no general strategy that allows simple and direct synthesis of nucleoside triphosphates. To face the challenges, we have developed a new approach in the absence of protecting groups to quickly and efficiently synthesized native deoxynucleoside 5-triphosphates and deoxynucleoside 5-(α- P-seleno)- P-seleno)triphosphates. Syntheses of the triphosphates containing selenium-derivatized nucleobases were also successfully accomplished. After replacing the oxygen atoms at the 4-position of thymidine and uridine, and the 6-position of guanosine, we observed most strikingly, a large bathrochromic shift of over 100 nm, relative to their native counterparts of UV absorbance of 260 nm. Consequently, the synthesized selenium base modified triphosphates are yellow. We also synthesized 2-selenothymidine and 5-methylseleno thymidine 5-triphosphates. We conducted stability study on the colored 4-selenothymidine and used the 5- triphosphate analog (4-SeTTP) as substrate for polymerase recognition. The Klenow polymerase incorporated the 4-SeTTP with efficiency equal to that of the native counterpart. Finally, 4-SeTTP was used to demonstrate UVdamage resistance of selenium-derivatized DNAs and plasmid.

Colored 4-selenothymidine

Plasmid

Klenow polymerase

Bathrochromic shift

Stability

Nucleic acids

Nucleoside 5½-triphosphates

Selenium-derivatized DNA

DNA flexibility

Duplex recognition

Chemistry

Advancements in Firefly Luciferase-Based Assays and Pyrosequencing Technology

Eriksson, Jonas

January 2004

<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 (c⁷dATP) 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, c⁷dATP, dATPαS.</p>

bioluminescence

osmolytes

glycine betaine

thermostability

firefly luciferase

inorganic pyrophosphatase

inorganic pyrophosphate

Pyrosequencing technology

secondary DNA-structures

Sequenase

Klenow-polymerase

reaction rates

temperature,

Effects of fusion tags on protein partitioning In aqueous two-phase systems and use in primary protein recovery

Hassinen, Cynthia

January 2002

The two techniques aqueoustwo-phase partitioning and expanded bed adsorption that bothare suitable for primary protein recovery were studied. Most ofthe work was focused on partition in aqueous two-phase systemsand in particular on the possibility to effect the partitionbehaviour by fusion of short peptide tags or protein domains tothe target protein. The partitioning of fusionproteins between different variants of the domain tag Z and thenaturally occurring protein DNA Klenow polymerase were studiedin Breox/Reppal aqueous two-phase systems. Most studies wereperformed with cell homogenate. The Breox/Reppal system was infocus because if the fusion protein can be partitioned to theBreox-rich top phase the next step can be a thermoseparatingaqueous two-phase system. When the Breox phase is heated to50°C it switches from a one-phase system to a two-phasesystem resulting in an almost pure water rich top phase andhighly concentrated Breox-rich bottom phase. The Breox can thenbe reused and the protein recovered from the water phase. TheZ-domain was genetically modified in different ways to Zbasic1, Zacid2and Ztrp12and fused to the Klenow protein to try toenhance partitioning to the Breox-rich phase. From theexperiments it was not possible to observe any effects on thepartition behaviour irrespectively of tested properties of thedomain tag. Despite the absence of domain tag effects highK-values, i.e. partition to the Breox-rich top phase, wereobserved in the Breox/Reppal system. However, the proteinK-values seemed to be rather sensitive to the cell homogenateload and showed a tendency to decrease with increased cellhomogenate load. Also increased phosphate concentration reducedthe K-values. The partitioning of cell debris also seemed todependent on the cell homogenate load. At higher homogenateload (&lt;=20g DW/L) clear Breox-rich top phases were observedwith the cell debris collected in Reppal-rich bottomphases. Two different tetrapeptides,AlaTrpTrpPro and AlaIleIlePro were inserted near the C-terminusof the protein ZZT0. The Trp-rich peptide unit stronglyincreased both the partitioning of ZZT0 into the poly(ethyleneglycol) (PEG)-rich phase in a PEG/potassium phosphate aqueoustwo-phase system and its retention on PEG and propylhydrophobic interaction chromatographic columns with potassiumphosphate as eluent in isocratic systems. Both the partitioningand the retention increased with increasing number of Trp-richpeptide units inserted into ZZT0. Insertion of Ile-richtetrapeptide units affected the partitioning and retention to amuch lesser extent. Partition and modelling data also indicateda folding of inserted Trp and Ile tetrapeptide units, probablyto minimise their water contact. It was also investigated howto predict the partitioning of proteins in isoelectricPEG/phosphate aqueous two-phase systems. The capture ofß-galactosidase fromE. colicell homogentate (50g DW/L) by metal chelatexpanded bed adsorption was studied. These experiments showedthat capture, with a certain degree of selectivity, andclarification of ß-galactosidase could be achieved from acell homogenate. However, a rather low recovery of about 35 %was obtained at a capacity of 0.25mg/mL of gel. Thus, severalparameters remain to be optimised like the load buffercomposition and the cell homogenate load. <b>Keywords:</b>E. coli, aqueous two-phase systems, fusion proteins,hydrophobic interaction chromatography, expanded bedadsorption, ß-galactosidase, Klenow polymerase, Z-domain,peptide tags / NR 20140805

E. coli

Aqueous two-phase systems

Fusion proteins

Hydrophobic interaction chromatography

Expanded bed adsorption

Beta-galactosidase

Klenow polymerase

Z-domain

Peptide tags